Maxtor 2B015H1, 2B020H1, 2B010H1 User Manual

Maxtor 541DX Product Manual

Models: 2B020H1, 2B015H1, 2B010H1

P/N:1546/A

This publication could include technical inaccuracies or typographical errors.
Changes are periodically made to the information herein – which will be incorporated
in revised editions of the publication. Maxtor may make changes or improvements
in the product(s) described in this publication at any time and without notice.

Copyright © 2001 Maxtor Corporation. All rights reserved. Maxtor
MaxFax® and No Quibble Service® are registered trademarks of Maxtor
Corporation. Other brands or products are trademarks or registered
trademarks of their respective holders.

®

,

Corporate Headquarters

500 McCarthy Blvd.
Milpitas, California 95035
Tel: 408-432-1700

Research and Development Center

2452 Clover Basin Drive
Longmont, Colorado 80503
Tel: 303-651-6000

Before YBefore Y

Before Y

Before YBefore Y

Thank you for your interest in Maxtor hard disk drives. This manual provides technical information for OEM
engineers and systems integrators regarding the installation and use of Maxtor hard drives. Drive repair should be
performed only at an authorized repair center. For repair information, contact the Maxtor Customer Service Center
at 800-2MAXTOR or 408-922-2085.

Before unpacking the hard drive, please review Sections 1 through 4.

ou Beginou Begin

ou Begin

ou Beginou Begin

CAUTION

Maxtor hard drives are precision products. Failure to follow these precautions

and guidelines outlined here may lead to product failure, damage

and invalidation of all warranties.

11

1

11

22

2

22

33

3 During handling,

33

44

4 Once a drive is removed from the Maxtor shipping container,

44

55

5

55

66

6

66

BEFORE unpacking or handling a drive, take all proper electro-static discharge (ESD)
precautions, including personnel and equipment grounding. Stand-alone drives are
sensitive to ESD damage.

BEFORE

temperature.

the drive through its mounting holes within a chassis. Otherwise, store the drive on a
padded, grounded, antistatic surface.

NEVER

into the drive's connector.

ELECTRICAL GROUNDING -

to a device bay that provides a suitable electrical ground to the drive baseplate.

removing drives from their packing material, allow them to reach room

NEVER

drop, jar, or bump a drive.

switch DC power onto the drive by plugging an electrically live DC source cable

NEVER

connect a live bus to the drive's interface connector.

For proper operation, the drive must be securely fastened

Please do not remove or cover up Maxtor factory-installed drive labels.

They contain information required should the drive ever need repair.

IMMEDIATELY

secure

ContentsContents

Contents

ContentsContents

Section 1 Section 1

Section 1 —

Section 1 Section 1

Maxtor Corporation 1 - 1

Products 1 - 1

Support 1 - 1

Manual Organization 1 - 1

Abbreviations 1 - 1

Conventions 1 - 2

Key Words 1 - 2

Numbering 1 - 2

Signal Conventions 1 - 2

Section 2 Section 2

Section 2 —

Section 2 Section 2

Product Features 2 - 2

Functional/Interface 2 - 2

Cache Management 2 - 4

Buffer Segmentation 2 - 4

Read-Ahead Mode 2 - 4

Automatic Write Reallocation (AWR) 2 - 4

Write Cache Stacking 2 - 4

Major HDA Components 2 - 5

Drive Mechanism 2 - 5

Rotary Actuator 2 - 5

Read/Write Electronics 2 - 5

Read/Write Heads and Media 2 - 5

Air Filtration System 2 - 5

Microprocessor 2 - 5

Subsystem Configuration 2 - 6

Dual Drive Support 2 - 6

Cable Select Option 2 - 6

Jumper Location/Configuration 2 - 6

Cylinder Limitation 2 - 6

Introduction Introduction

Introduction

Introduction Introduction

Product Description Product Description

Product Description

Product Description Product Description

Zone Density Recording 2 - 2

Read/Write Multiple Mode 2 - 2

Ultra ATA - Mode 5 2 - 2

Multi-word DMA (EISA Type B) - Mode 2 2 - 2

Sector Address Translation 2 - 2

Logical Block Addressing 2 - 3

Defect Management Zone 2 - 3

On-the-Fly Hardware Error Correction Code (ECC) 2 - 3

Software ECC Correction 2 - 3

Automatic Head Park and Lock Operation 2 - 3

i

Section 3 Section 3

Section 3 —

Section 3 Section 3

Models and Capacities 3 - 1

Drive Configuration 3 - 1

Performance Specifications 3 - 1

Physical Dimensions 3 - 2

Power Requirements 3 - 3

Power Mode Definitions 3 - 3

Spin-up 3 - 3

Seek 3 - 3

Read/Write 3 - 3

Idle 3 - 3

Standby 3 - 3

Sleep 3 - 3

EPA Energy Star Compliance 3 - 3

Environmental Limits 3 - 3

Shock and Vibration 3 - 4

Reliability Specifications 3 - 4

Annual Return Rate 3 - 4

Quality Acceptance Rate 3 - 4

Start/Stop Cycles 3 - 4

Data Reliability 3 - 4

Component Design Life 3 - 4

EMC/EMI 3 - 5

EMC Compliance 3 - 5

Canadian Emissions Statement 3 - 5

Safety Regulatory Compliance 3 - 5

Product Specifications Product Specifications

Product Specifications

Product Specifications Product Specifications

Section 4 Section 4

Section 4 —

Section 4 Section 4

Hard Drive Handling Precautions 4 - 1

Electro-Static Discharge (ESD) 4 - 1

Unpacking and Inspection 4 - 2

Repacking 4 - 3

Physical Installation 4 - 3

Before You Begin 4 - 4

Please Read 4 - 4

Back up. Protect Your Existing Data 4 - 4

Tools for Installation 4 - 4

System Requirements 4 - 4

Operating System Requirements 4 - 4

Hook up 4 - 4

Boot the System with MaxBlast Plus Diskette 4 - 4

Configure the Drive Jumpers 4 - 4

Installaing 5.25-inch Mounting Brackets 4 - 4

Install Hard Drive in Device Bay 4 - 5

Attach Interface and Power Cables 4 - 5

Start up 4 - 5

Set up 4 - 5

Handling and Installation Handling and Installation

Handling and Installation

Handling and Installation Handling and Installation

ii

Section 5 Section 5

Section 5 —

Section 5 Section 5

Interface Connector 5 - 1

Pin Description Summary 5 - 1

Pin Description Table 5 - 2

PIO Timing 5 - 3

DMA Timing 5 - 4

Ultra DMA Timing Parameters 5 - 5

AT Interface Description AT Interface Description

AT Interface Description

AT Interface Description AT Interface Description

Section 6 Section 6

Section 6 —

Section 6 Section 6

Task File Registers 6 - 1

Data Register 6 - 1

Error Register 6 - 1

Features Register 6 - 1

Sector Count Register 6 - 2

Sector Number Register 6 - 2

Cylinder Number Registers 6 - 2

Device/Head Register 6 - 2

Status Register 6 - 2

Command Register 6 - 3

Read Commands 6 - 3

Write Commands 6 - 3

Mode Set/Check Commands 6 - 3

Power Mode Commands 6 - 3

Initialization Commands 6 - 3

Seek, Format, and Diagnostic Commands 6 - 3

S.M.A.R.T. Commands 6 - 3

Summary 6 - 4

Control Diagnostic Registers 6 - 5

Alternate Status Register 6 - 5

Device Control Register 6 - 5

Digital Input Register 6 - 5

Reset and Interrupt Handling 6 - 6

Host Software Interface Host Software Interface

Host Software Interface

Host Software Interface Host Software Interface

Section 7 Section 7

Section 7 —

Section 7 Section 7

Command Summary 7 - 1

Read Commands 7 - 2

Write Commands 7 - 4

Interface Commands Interface Commands

Interface Commands

Interface Commands Interface Commands

Read Sector(s) 7 - 2

Read Verify Sector(s) 7 - 2

Read Sector Buffer 7 - 2

Read DMA 7 - 3

Read Multiple 7 - 3

Set Multiple 7 - 3

Write Sector(s) 7 - 4

iii

Write Verify Sector(s) 7 - 4

Write Sector Buffer 7 - 4

Write DMA 7 - 5

Write Multiple 7 - 5

Mode Set/Check Commands 7 - 6

Set Features Mode 7 - 6

Read Native Max Address 7 - 7

Set Max 7 - 7

Set Max Password 7 - 7

Set Max Lock 7 - 7

Set Max Unlock 7 - 7

Set Max Freeze Lock 7 - 7

Power Mode Commands 7 - 8

Standby Immediate 7 - 8

Idle Immediate 7 - 8

Standby 7 - 8

Idle 7 - 8

Check Power Mode 7 - 8

Set Sleep Mode 7 - 8

Default Power-on Condition 7 - 9

Initialization Commands 7 - 10

Identify Drive 7 - 10

Initialize Drive Parameters 7 - 13

Seek, Format, and Diagnostic Commands 7 - 14

S.M.A.R.T. Command Set 7 - 15

Section 8 Section 8

Section 8 —

Section 8 Section 8

Service Policy 8 - 1

No Quibble Service 8 - 1

Support 8 - 1

GlossaryGlossary

Glossary

GlossaryGlossary

Service and Support Service and Support

Service and Support

Service and Support Service and Support

iv

FiguresFigures

Figures

FiguresFigures

Figure Title Page

2 - 1 PCBA Jumper Location and Configuration 2 - 6

3 - 1 Outline and Mounting Dimensions 3 - 2

4 - 1 Multi-pack Shipping Container 4 - 2

4 - 2 Single-pack Shipping Container (Option A) 4 - 3

4 - 3 Single-pack Shipping Container (Option B) 4 - 3

4 - 4 IDE Interface and Power Cabling Detail 4 - 5

5 - 1 Data Connector 5 - 1

5 - 2 PIO Data Transfer to/from Device 5 - 3

5 - 3 Multi-word DMA Data Transfer 5 - 4

5 - 4 Initiating an Ultra DMA Data In Burst 5 - 5

5 - 5 Sustained Ultra DMA Data In Burst 5 - 6

5 - 6 Host Pausing an Ultra DMA Data In Burst 5 - 6

5 - 7 Device Terminating an Ultra DMA Data In Burst 5 - 7

5 - 8 Host Terminating an Ultra DMA Data In Burst 5 - 7

5 - 9 Initiating an Ultra DMA Data Out Burst 5 - 8

5 - 10 Sustained Ultra DMA Data Out Burst 5 - 8

5 - 11 Device Pausing an Ultra DMA Data Out Burst 5 - 9

5 - 12 Host Terminating an Ultra DMA Data Out Burst 5 - 9

5 - 13 Device Terminating an Ultra DMA Data Out Burst 5 - 10

v

SECTION 1

IntroductionIntroduction

Introduction

IntroductionIntroduction

Maxtor CorporationMaxtor Corporation

Maxtor Corporation

Maxtor CorporationMaxtor Corporation

Maxtor Corporation has been providing high-quality computer storage products since 1982. Along the way,
we’ve seen many changes in data storage needs. Not long ago, only a handful of specific users needed more than
a couple hundred megabytes of storage. Today, downloading from the Internet and CD-ROMs, multimedia,
networking and advanced office applications are driving storage needs even higher. Even home PC applications
need capacities measured in gigabytes, not megabytes.

ProductsProducts

Products

ProductsProducts

Maxtor’s products meet the demanding data storage capacity requirements of today and tomorrow. They are
available in 5400- and 7200- RPM configurations with capacity offerings from 10 to 80 GB and beyond.

SupportSupport

Support

SupportSupport

No matter which capacity, all Maxtor hard drives are supported by our commitment to total customer
satisfaction and our No Quibble Service
(www.maxtor.com) – puts you in touch with either technical support or customer service. We’ll provide
you the information you need quickly, accurately and in the form you prefer – a fax, a downloaded file or
a conversation with a representative.

®

guarantee. One call – or a visit to our home page on the Internet

INTRODUCTION

Manual OrganizationManual Organization

Manual Organization

Manual OrganizationManual Organization

This hard disk drive reference manual is organized in the following method:

Section 1 – Introduction
Section 2 – Product Description
Section 3 – Product Specifications
Section 4 – Handling and Installation
Section 5 – AT Interface Description
Section 6 – Host Software Interface
Section 7 – Interface Commands
Section 8 – Service and Support
Appendix – Glossary

AbbreviationsAbbreviations

Abbreviations

AbbreviationsAbbreviations

ABBRV DESCRIPTION ABBRV DESCRIPTION

ATA AT attachment MB megab yte

bpi bits per i nch Mbits/sec meg ab i ts p e r s econd

CHS cylinder - he ad - sector MB/sec megabytes per second

db decibels MHz megahert z

d BA dec ibels, A wei ghted m s mill i s ec ond
DMA d i rect me mo ry access MSB most si gnificant bit
ECC error correction code mV m illivolts

fc i fl ux c hange s pe r i nch ns n ano se co nds

G acceler ation P IO programmed input/ output

GB gi gabyte RPM revolutions per minute

Hz hertz tp i tracks per inch

KB ki lobyte UDMA ultra direct memo ry a cce ss
LBA logical block address(ing) µsec microsecond
L SB l east s ig nificant bit V volt s

mA milliamperes W watts

1 – 1

INTRODUCTION

ConventionsConventions

Conventions

ConventionsConventions

If there is a conflict between text and tables, the table shall be accepted as being correct.

Key WordsKey Words

Key Words

Key WordsKey Words

NumberingNumbering

Numbering

NumberingNumbering

Signal ConventionsSignal Conventions

Signal Conventions

Signal ConventionsSignal Conventions

The names of abbreviations, commands, fields and acronyms used as signal names are in all uppercase type
(e.g., IDENTIFY DRIVE). Fields containing only one bit are usually referred to as the “name” bit instead of
the “name” field.

Names of drive registers begin with a capital letter (e.g., Cylinder High register).

Numbers that are not followed by a lowercase “b” or “h” are decimal values. Numbers that are followed by
a lowercase “b” (e.g., 01b) are binary values. Numbers that are followed by a lowercase “h” (e.g., 3Ah) are
hexadecimal values.

Signal names are shown in all uppercase type.

All signals are either high active or low active signals. A dash character (-) at the end of a signal name
indicates that the signal is low active. A low active signal is true when it is below ViL and is false when it is
above ViH. A signal without a dash at the end indicates that the signal is high active. A high active signal is
true when it is above ViH and is false when it is below ViL.

When a signal is asserted, it means the signal is driven by an active circuit to its true state.

When a signal is negated, it means the signal is driven by an active circuit to its false state.

When a signal is released, it means the signal is not actively driven to any state. Some signals have bias
circuitry that pull the signal to either a true or false state when no signal driver is actively asserting or negating
the signal. These instances are noted under the description of the signal.

1 – 2

PRODUCT DESCRIPTION

SECTION 2

ProductProduct

Product

ProductProduct

Maxtor hard disk drives are 17.5 mm high, 3.5-inch diameter random access storage devices which incorporate an
on-board Ultra ATA/100 interface controller. High capacity is achieved by a balanced combination of high areal
recording density and the latest data encoding and servo techniques.

Maxtor's latest advancements in electronic packaging and integration methods have lowered the drive's power
consumption and increased its reliability. Exceptional data transfer speeds, 5400 RPM spin speed and 12 ms access
times make these entry-class disk drives ideally-suited to desktop storage and consumer electronics applications.

Key FeaturesKey Features

Key Features

Key FeaturesKey Features

ANSI ATA-5/6 compliant PIO Mode 5 interface (Enhanced IDE)

Supports Ultra DMA Mode 5 for up to 100 MBytes/sec data transfers

2 MB buffer with multi-adaptive cache manager

5400 RPM spin speed

12 ms seek time

Zone density and I.D.-less recording

Outstanding shock resistance at 300 Gs

DescriptionDescription

Description

DescriptionDescription

Custom load/unload ramp feature

High durability with 50K contact start/stop cycles

Advanced multi-burst on-the-fly Error Correction Code (ECC)

Extended data integrity with ECC protected data and fault tolerant servo synchronization fields

Supports EPA Energy Star Standards (Green PC Friendly) with ATA powering savings commands

Auto park and lock actuator mechanism

Low power consumption

S.M.A.R.T. Capability

Note: GB means 1 billion bytes. Total accessible capacity varies depending on operating environment.

2 – 1

PRODUCT DESCRIPTION

ProductProduct

Product

ProductProduct

Functional / InterfaceFunctional / Interface

Functional / Interface

Functional / InterfaceFunctional / Interface

Maxtor hard drives contain all necessary mechanical and electronic parts to interpret control signals and
commands from an AT-compatible host computer. See Section 3 Product Specifications, for complete
drive specifications.

Zone Density RecordingZone Density Recording

Zone Density Recording

Zone Density RecordingZone Density Recording

Read / Write Multiple ModeRead / Write Multiple Mode

Read / Write Multiple Mode

Read / Write Multiple ModeRead / Write Multiple Mode

UltraDMA - Mode 5UltraDMA - Mode 5

UltraDMA - Mode 5

UltraDMA - Mode 5UltraDMA - Mode 5

Multi-word DMA (EISA Type B) - Mode 2Multi-word DMA (EISA Type B) - Mode 2

Multi-word DMA (EISA Type B) - Mode 2

Multi-word DMA (EISA Type B) - Mode 2Multi-word DMA (EISA Type B) - Mode 2

FeaturesFeatures

Features

FeaturesFeatures

The disk capacity is increased with bit density management – common with Zone Density Recording.
Each disk surface is divided into 16 circumferential zones. All tracks within a given zone contain a
constant number of data sectors. The number of data sectors per track varies in different zones; the
outermost zone contains the largest number of data sectors and the innermost contains the fewest.

This mode is implemented per ANSI ATA/ATAPI-5 specification. Read/Write Multiple allows the
host to transfer a set number of sectors without an interrupt request between them, reducing transfer
process overhead and improving host performance.

Maxtor hard drives fully comply with the new ANSI Ultra DMA protocol, which greatly improves
overall AT interface performance by significantly improving burst and sustained data throughput.

Supports multi-word Direct Memory Access (DMA) EISA Type B mode transfers.

Sector Address TranslationSector Address Translation

Sector Address Translation

Sector Address TranslationSector Address Translation

All Maxtor hard drives feature a universal translate mode. In an AT/EISA-class system, the drive may
be configured to any specified combination of cylinders, heads and sectors (within the range of the
drive's formatted capacity). Maxtor hard drives power-up in a translate mode:

MOD EL S C YL HD SP T MAX LB A C APACI TY

2B020H1 39 703 16 63 40 020 624 20.4 GB

2B015H1 29 975 16 63 30 214 800 15.4 GB

2B010H1 19 854 16 63 20 012 832 10.2 GB

Logical Block AddressingLogical Block Addressing

Logical Block Addressing

Logical Block AddressingLogical Block Addressing

The Logical Block Address (LBA) mode can only be utilized in systems that support this form of translation.
The cylinder, head and sector geometry of the drive, as presented to the host, differs from the actual physical
geometry. The host AT computer may access a drive of set parameters: number of cylinders, heads and sectors
per track, plus cylinder, head and sector addresses. However, the drive can’t use these host parameters directly
because of zoned recording techniques. The drive translates the host parameters to a set of logical internal
addresses for data access.

The host drive geometry parameters are mapped into an LBA based on this formula:

LBA = (HSCA - 1) + HHDA x HSPT + HNHD x HSPT x HCYA (1)

whe re HSCA = Host Sector Address, HHDA = Host Head Address

The LBA is checked for violating the drive capacity. If it does not, the LBA is converted to physical drive
cylinder, head and sector values. The physical address is then used to access or store the data on the disk
and for other drive related operations.

= (HSCA - 1) + HSPT x (HHDA + HNHD x HCYA) (2)

HCYA = Host Cylinder Address, HNHD = Host Number of Heads
HSPT = Host Sectors per Track

2 – 2

Defect Management Zone (DMZ)Defect Management Zone (DMZ)

Defect Management Zone (DMZ)

Defect Management Zone (DMZ)Defect Management Zone (DMZ)

Each drive model has a fixed number of spare sectors per drive, all of which are located at the end of the
drive. Upon detection of a bad sector that has been reassigned, the next sequential sector is used.

For example, if sector 3 is flagged, data that would have been stored there is “pushed down” and recorded
in sector 4. Sector 4 then effectively becomes sector 3, as sequential sectors are “pushed down” across the
entire drive. The first spare sector makes up for the loss of sector 3, and so maintains the sequential order
of data. This push down method assures maximum performance.

On-the-Fly Hardware Error Correction Code (ECC)On-the-Fly Hardware Error Correction Code (ECC)

On-the-Fly Hardware Error Correction Code (ECC)

On-the-Fly Hardware Error Correction Code (ECC)On-the-Fly Hardware Error Correction Code (ECC)

14 symbols, single burst, guaranteed.

Software ECC CorrectionSoftware ECC Correction

Software ECC Correction

Software ECC CorrectionSoftware ECC Correction

24 symbols, single burst, guaranteed.

Automatic Park and Lock OperationAutomatic Park and Lock Operation

Automatic Park and Lock Operation

Automatic Park and Lock OperationAutomatic Park and Lock Operation

Immediately following power down, dynamic braking of the spinning disks delays momentarily allowing
the read/write heads to move to an inner mechanical stop. A small fixed magnet holds the rotary actuator
in place as the disk spins down. The rotary actuator is released only when power is again applied.

Cache ManagementCache Management

Cache Management

Cache ManagementCache Management

Buffer SegmentationBuffer Segmentation

Buffer Segmentation

Buffer SegmentationBuffer Segmentation

The data buffer is organized into two segments: the data buffer and the micro controller scratch pad.
The data buffer is dynamically allocated for read and write data depending on the commands received.
A variable number of read and write buffers may exist at the same time.

PRODUCT DESCRIPTION

Read-Ahead ModeRead-Ahead Mode

Read-Ahead Mode

Read-Ahead ModeRead-Ahead Mode

Normally, this mode is active. Following a read request, disk read-ahead begins on the first sector and
continues sequentially until the allocated buffer is full. If a read request is received during the read-ahead
operation, the buffer is examined to determine if the request is in the cache. If a cache hit occurs, read­ahead mode continues without interruption and the host transfer begins immediately.

Automatic Write Reallocation (AWR)Automatic Write Reallocation (AWR)

Automatic Write Reallocation (AWR)

Automatic Write Reallocation (AWR)Automatic Write Reallocation (AWR)

This feature is part of the write cache and reduces the risk of data loss during deferred write operations.
If a disk error occurs during the disk write process, the disk task stops and the suspect sector is reallocated
to a pool of alternate sectors located at the end of the drive. Following reallocation, the disk write task
continues until it is complete.

Write Cache StackingWrite Cache Stacking

Write Cache Stacking

Write Cache StackingWrite Cache Stacking

Normally, this mode is active. Write cache mode accepts the host write data into the buffer until the buffer
is full or the host transfer is complete. A command complete interrupt is generated at the end of the transfer.

A disk write task begins to store the host data to disk. Host write commands continue to be accepted
and data transferred to the buffer until either the write command stack is full or the data buffer is full.
The drive may reorder write commands to optimize drive throughput.

2 – 3

PRODUCT DESCRIPTION

Major HDA ComponentsMajor HDA Components

Major HDA Components

Major HDA ComponentsMajor HDA Components

Drive MechanismDrive Mechanism

Drive Mechanism

Drive MechanismDrive Mechanism

A brush-less DC direct drive motor rotates the spindle at 5400 RPM (±0.1%). The dynamically balanced
motor/spindle assembly ensures minimal mechanical run-out to the disks. A dynamic brake provides a fast
stop to the spindle motor upon power removal. The speed tolerance includes motor performance and
motor circuit tolerances.

Rotary ActuatorRotary Actuator

Rotary Actuator

Rotary ActuatorRotary Actuator

All Maxtor hard drives employ a rotary voice coil actuator which consists of a moving coil, an actuator
arm assembly and stationary magnets. The actuator moves on a low-mass, low-friction center shaft. The
low friction contributes to fast access times and low power consumption.

Read/Write ElectronicsRead/Write Electronics

Read/Write Electronics

Read/Write ElectronicsRead/Write Electronics

An integrated circuit mounted within the sealed head disk assembly (near the read/write heads) provides
up to eight head selection (depending on the model), read pre-amplification and write drive circuitry.

Read/Write Heads and MediaRead/Write Heads and Media

Read/Write Heads and Media

Read/Write Heads and MediaRead/Write Heads and Media

Low mass, low force giant magneto-resistive read/write heads record data on 3.5-inch diameter disks.
Maxtor uses a sputtered thin film medium on all disks for Maxtor hard drives.

Air Filtration SystemAir Filtration System

Air Filtration System

Air Filtration SystemAir Filtration System

All Maxtor hard drives are assembled in a Class 100 controlled environment. Over the life of the drive,
a 0.1 micron filter and breather filter located within the sealed head disk assembly (HDA) maintain a clean
environment to the heads and disks. Maxtor drives are designed to operate in a typical office environment
with minimum environmental control.

MicroprocessorMicroprocessor

Microprocessor

MicroprocessorMicroprocessor

The microprocessor controls the following functions for the drive electronics:

Command execution

Cache management

Data correction and error recovery

Diagnostic execution

Data sequencing

Head positioning (including error recovery)

Host interface

Index detection

Spin speed control

Seeks

Servo

S.M.A.R.T.

2 – 4

PRODUCT DESCRIPTION

Subsystem ConfigurationSubsystem Configuration

Subsystem Configuration

Subsystem ConfigurationSubsystem Configuration

Dual Drive SupportDual Drive Support

Dual Drive Support

Dual Drive SupportDual Drive Support

Two drives may be accessed via a common interface cable, using the same range of I/O addresses.
The drives are jumpered as device 0 or 1 (Master/Slave), and are selected by the drive select bit in the
Device/Head register of the task file.

All Task File registers are written in parallel to both drives. The interface processor on each drive decides
whether a command written to it should be executed; this depends on the type of command and which
drive is selected. Only the drive selected executes the command and activates the data bus in response to
host I/O reads; the drive not selected remains inactive.

A master/slave relationship exists between the two drives: device 0 is the master and device 1 the slave.
When the Master is closed (factory default, figure 2-1), the drive assumes the role of master; when open, the
drive acts as a slave. In single drive configurations, the Master jumper must be closed.

Cable Select OptionCable Select Option

Cable Select Option

Cable Select OptionCable Select Option

CSEL (cable select) is an optional feature per ANSI ATA specification. Drives configured in a multiple
drive system are identified by CSEL’s value:

– If CSEL is grounded, then the drive address is 0.
– If CSEL is open, then the drive address is 1.

Jumper Location / ConfigurationJumper Location / Configuration

Jumper Location / Configuration

Jumper Location / ConfigurationJumper Location / Configuration

J UM PE R CON F IGU RAT ION

Maste r/Slave
Only drive in single drive system*
Master drive in dual drive system*
Slave drive in dual drive system

Cable Select
Disabled*
E nabled

Cylinder Limitation
Disabled*
E nabled

Factory Reserved O

Key * = Default C = Closed (jum per ins tal led) O = Open (no j umper)

C
C
O

O
C

Figure 2-1

PCBA Jumper Location and Configuration

Cylinder Limitation Jumper DescriptionCylinder Limitation Jumper Description

Cylinder Limitation Jumper Description

Cylinder Limitation Jumper DescriptionCylinder Limitation Jumper Description

On some older BIOS', primarily those that auto-configure the disk drive, a hang may occur. The Cylinder
Limitation jumper reduces the capacity in the Identify Drive allowing large capacity drives to work with
older BIOS'. The capacity reported when this jumper is closed will be as follows: drives less than or equal to
32GB will report 2.1GB. Drives greater than 32GB will report 32GB.

O
C

2 – 5

Product SpecificationsProduct Specifications

Product Specifications

Product SpecificationsProduct Specifications

Models and CapacitiesModels and Capacities

Models and Capacities

Models and CapacitiesModels and Capacities

MODELS 2B020H1 2B015H1 2B010H1

Formatted Capacity

GB me ans 1 bi lli on bytes. To tal accessi ble capacity varies dependi ng on
operating env ironment.

Drive ConfigurationDrive Configuration

Drive Configuration

Drive ConfigurationDrive Configuration

MODELS 2B020H1 2B015H1 2B010H1

Integrated Interface ATA-5 and ATA-6 / Ultra ATA/100

Encoding Method E

Interleave 1:1

Servo System Em bed d ed

Data Buffer Size

Data Buffer Type SDRAM

Data Zones per Surface 16

Data Surfaces/Hea ds 1

Number of Disks 1

Areal Density

Tra ck Density

Recording Density

Bytes per Sector/Block 512

Sector s per Track

Sectors per Drive 40 020 624 30 214 800 20 012 832

(GB L BA Mod e)

(MByte)

(Gbits/in2 m ax, ID / OD)

(ktpi)

(kbpi, ID / OD)

(ID / OD)

20.4 GB 15.4 GB 10.2 GB

2

PR4 RLL 16/17

2

31.4 / 26.6

54

575 / 471

608 / 968

PRODUCT SPECIFICATIONS

SECTION 3

Performance SpecificationsPerformance Specifications

Performance Specifications

Performance SpecificationsPerformance Specifications

MODELS 2B 020H1 2B015H1 2B010H1

Seek Times

Track-to-Track 1

Average

Full S troke

Average Latency

Controller Overhead

Rotation Speed

Data Transfer Spe ed

To /F rom Inter face

(Ultra ATA/100 - M5

To/From Media

Sustained

Drive Ready Time

(typical read, ms)

(normal seek)

(normal seek)

(m s)

(m s)

(RPM ±0.1%)

(MByte/sec max)

)

(I D / O D)

(I D / O D)

(typi cal s ec

12

19

5.51

< 0. 3

5400

100

29.6 / 46.4

25.0 / 39.3

)

5

3 – 1

PRODUCT SPECIFICATIONS

Physical DimensionsPhysical Dimensions

Physical Dimensions

Physical DimensionsPhysical Dimensions

3 – 2

PARAM ETER VALU E

Height

(typical mm) 17.0

(typical mm)

Width

(typical mm) 146.1

Length

Wei ght

(m ax kg ) 0.453

101.6

Power RequirementsPower Requirements

e

Power Requirements

Power RequirementsPower Requirements

MODE 12V (ma) 5V (ma) POW ER (w)

Spin-up (peak) 2050 350 --

Seek 260 350 6.0

Read/Write 260 350 5.4

Idle 190 250 4.0

Standby 30 125 1.4

Sleep 30 90 1.2

Power Mode DefinitionsPower Mode Definitions

Power Mode Definitions

Power Mode DefinitionsPower Mode Definitions

Spin-upSpin-up

Spin-up

Spin-upSpin-up

The drive is spinning up following initial application of power and has not yet reached full speed.

SeekSeek

Seek

SeekSeek

A random access operation by the disk drive.

Read/WriteRead/Write

Read/Write

Read/WriteRead/Write

Data is being read from or written to the drive.

PRODUCT SPECIFICATIONS

IdleIdle

Idle

IdleIdle

The drive is spinning, the actuator is parked and powered off and all other circuitry is powered on.
The drive is capable of responding to read commands within 40 ms.

StandbyStandby

Standby

StandbyStandby

The spin motor is not spinning. The drive will leave this mode upon receipt of a command that requires
disk access. The time-out value for this mode is programmable. The buffer is active to accept write data.

SleepSleep

Sleep

SleepSleep

This is the lowest power state – with the interface set to inactive. A software or hardware reset is required
to return the drive to the Standby state.

EPA Energy Star ComplianceEPA Energy Star Compliance

EPA Energy Star Compliance

EPA Energy Star ComplianceEPA Energy Star Compliance

Maxtor Corporation supports the goals of the U.S. Environmental Protection Agency’s Energy Star program
to reduce the electrical power consumption of computer equipment.

Environmental LimitsEnvironmental Limits

Environmental Limits

Environmental LimitsEnvironmental Limits

PARAM ETER OP ER AT ING NON-OP ERATIN G/ST OR AGE

Temperature 5° C to 55° C low temperature (-40° C)

high temperature (71° C) per MIL-S

501.3, climatic c ategory; hot-induc

Thermal Gradient 25° C per hour (maximum)

Relati ve Humidi ty 5% to 9 5% (non-condensing)

Wet Bulb 27° C (ma xi m um)

Altitude (relative to sea level) -200 to 10,000 feet -200 to 40,000 feet

Acoustic Noise - sound power

(per ISO 7779, 10 mic rophone,
at sea level)

Idle mode

3.0 bel average

3.4 bel maximum

Normal Seek mode

3.3 bel average

3.8 bel maximum

3 – 3

PRODUCT SPECIFICATIONS

Shock and VibrationShock and Vibration

Shock and Vibration

Shock and VibrationShock and Vibration

PARAM ETER O PER AT ING N ON-O PER AT ING

Mechanical Shoc k 30 Gs, 2.0 ms, no errors 300 Gs, 2.0 ms, no damage

Rotational Shock 20,000 Rad/sec,0.5 to 1.0 ms, no d

Random Vibration 10 to 45 Hz at 0.004 G

Swept Sine Vibration
10 to 300 Hz 1 G (0 to peak) amplitude, 1 octave per minute

Reliability SpecificationsReliability Specifications

Reliability Specifications

Reliability SpecificationsReliability Specifications

Annual Return RateAnnual Return Rate

Annual Return Rate

Annual Return RateAnnual Return Rate

<0.5% Annual Return Rate (ARR) indicates the average against products shipped.

2

/Hz

48 to 62 Hz at 0.008 G
65 to 300 Hz at 0.004 G
301 to 500 Hz at 0.0006 G
no errors

2

/Hz

2

ARR includes all reasons for returns (failures, handling damage, NDF), but
does not include inventory credit returns.

/Hz

2

/Hz

PSD:
10 Hz at .05 G
20 Hz at .055 G
300 Hz at .05 G
301 Hz at .0014 G
500 Hz at .001 G
760 Hz at .001 G
877 Hz at .003 G
1000 Hz at .001 G
1570 Hz at .001 G
2000 Hz at .0001 G

2

/Hz

2

2

/Hz,
/Hz

2

2

2

2

/Hz
/Hz
/Hz

2

2

/Hz

/Hz
/Hz

2

/Hz

Quality Acceptance RateQuality Acceptance Rate

Quality Acceptance Rate

Quality Acceptance RateQuality Acceptance Rate

<1,000 DPPM The quality acceptance rate indicates the percentage of Maxtor products

successfully installed by our customers, and/or the number of defective parts
per million (DPPM) encountered during the entire installation process.

Start/Stop CyclesStart/Stop Cycles

Start/Stop Cycles

Start/Stop CyclesStart/Stop Cycles

>50,000 This indicates the average minimum cycles for reliable start/stop function.

Load/Unload CyclesLoad/Unload Cycles

Load/Unload Cycles

Load/Unload CyclesLoad/Unload Cycles

>100,000 This indicates the average minimum cycles for reliable load/unload function.

Data ReliabilityData Reliability

Data Reliability

Data ReliabilityData Reliability

<1 per 10E14 bits read Data errors (non-recoverable). Average data error rate allowed with all error

recovery features activated.

Component Design LifeComponent Design Life

Component Design Life

Component Design LifeComponent Design Life

5 years (minimum) Component design life is defined as a.) the time period before identified

wear-out mechanisms impact the failure rate, or b.) the time period up to the
wear-out point when useful component life expires.

3 – 4

PRODUCT SPECIFICATIONS

EMC/EMIEMC/EMI

EMC/EMI

EMC/EMIEMC/EMI

Radiated Electromagnetic Field Emissions - EMC ComplianceRadiated Electromagnetic Field Emissions - EMC Compliance

Radiated Electromagnetic Field Emissions - EMC Compliance

Radiated Electromagnetic Field Emissions - EMC ComplianceRadiated Electromagnetic Field Emissions - EMC Compliance

The hard disk drive mechanism is designed as a subassembly for installation into a suitable enclosure and is
therefore not subject to Subpart J of Part 15 of FCC Rules (47CFR15) or the Canadian Department of
Communications Radio Interference Regulations. Although not required, the disk mechanism has been
tested within a suitable end-use product and found to comply with Class B limits of the FCC Rules and
Regulations of the Canadian Department of Communications.

The CE Marking indicates conformity with the European Union Low Voltage Directive (73/23/EEC) when
the disk mechanism is installed in a typical personal computer. Maxtor recommends that testing and analysis
for EMC compliance be performed with the disk mechanism installed within the user's end-use application.

Canadian Emissions StatementCanadian Emissions Statement

Canadian Emissions Statement

Canadian Emissions StatementCanadian Emissions Statement

This digital apparatus does not exceed the Class B limits for radio noise emissions from digital apparatus as set
out in the radio interference regulations of the Canadian department of communications.

Le present appareil numerique n'emet pas de bruit radioelectriques depassant les limites applicables aux
appareils numeriques de Class B prescrites dans le reglement sur le brouillage radioelectrique edicte par le
ministere des communications du Canada.

Safety Regulatory ComplianceSafety Regulatory Compliance

Safety Regulatory Compliance

Safety Regulatory ComplianceSafety Regulatory Compliance

All Maxtor hard drives comply with relevant product safety standards such as CE, CUL, TUV and UL rules and
regulations. As delivered, Maxtor hard drives are designed for system integration before they are used.

3 – 5

SECTION 4

Handling and InstallationHandling and Installation

Handling and Installation

Handling and InstallationHandling and Installation

Hard Drive Handling PrecautionsHard Drive Handling Precautions

Hard Drive Handling Precautions

Hard Drive Handling PrecautionsHard Drive Handling Precautions

◆ If the handling precautions are not followed, damage to the hard drive may result - which may void the warranty.

◆ During handling, NEVER drop, jar, or bump a drive. Handle the drive by its sides and avoid touching the printed circuit board

assembly (PCBA).

◆ Hard drives are sensitive to electrostatic discharge (ESD) damage. Use proper ESD practices by grounding yourself and the

computer system the hard drive will be installed in.

◆ Allow the hard drive to reach room temperature BEFORE installing it in your computer system.

◆ NEVER switch DC power onto the drive by plugging an electrically live DC source cable into the drive's connector. NEVER

connect a live connector to the hard drive's IDE interface connector.

◆ ELECTRICAL GROUNDING - For proper operation, the drive must be securely fastened to a device bay

that provides a suitable electrical ground to the drive baseplate.

INSTALLATION

Electro-Static Discharge (ESD)Electro-Static Discharge (ESD)

Electro-Static Discharge (ESD)

Electro-Static Discharge (ESD)Electro-Static Discharge (ESD)

To avoid some of the problems associated with ESD, Maxtor advises that anyone handling a disk drive use a
wrist strap with an attached wire connected to an earth ground. Failure to observe these precautions voids the
product warranty.

Manufacturers frequently experience “unsolved” component/hardware malfunctions often caused by ESD. To
reduce the incidence of ESD-related problems, Maxtor recommends that any electronics manufacturing plans
include a comprehensive ESD program, the basic elements and functions of which are outlined here:

ESD Program Element ESD Program Function
Management Institute and maintain
Chief coordinator Organize and enforce
Multi-department committee Evaluate and improve
Employee training Educate and inform

ESD program supplies typically include: wrist- and foot-worn grounding straps; counter-top and floor antistatic
matting; wrist strap testers; ESD video and training materials. Sources for such supplies include:

Static Control Systems – 3M Charleswater
225-4S, 3M Center 93 Border St.
St. Paul, MN 55144 West Newton, MA 02165-9990

Maxtor also offers a complete video training package, “Care and Handling of Maxtor Disk Drives.”
Contact your Maxtor representative for details.

4 – 1

INSTALLATION

Unpacking and InspectionUnpacking and Inspection

Unpacking and Inspection

Unpacking and InspectionUnpacking and Inspection

Retain any packing material for reuse. Inspect the shipping container for evidence of damage in transit. Notify
the carrier immediately in case of damage to the shipping container.

As they are removed, inspect drives for evidence of shipping damage or loose hardware. If a drive is damaged
(and no container damage is evident), notify Maxtor immediately for drive disposition.

4 – 2

Figure 4 - 1

Multi-pack Shipping Container

INSTALLATION

Single Pack Shipping Container (Option A)

RepackingRepacking

Repacking

RepackingRepacking

Figure 4 - 2

Single Pack Shipping Container (Option B)

Figure 4 - 3

If a Maxtor drive requires return, repack it using Maxtor packing materials, including the antistatic bag.

Physical InstallationPhysical Installation

Physical Installation

Physical InstallationPhysical Installation

Recommended Mounting ConfigurationRecommended Mounting Configuration

Recommended Mounting Configuration

Recommended Mounting ConfigurationRecommended Mounting Configuration

The Maxtor hard drive design allows greater shock tolerance than that afforded by larger, heavier drives. The
drive may be mounted in any attitude using four size 6-32 screws with 1/8-inch maximum penetration and a
maximum torque of 5-inch pounds. See Figure 3-1 for mounting dimensions. Allow adequate ventilation to
the drive to ensure reliable operation. See the following pages for specific installation steps.

4 – 3

INSTALLATION

Before You BeginBefore You Begin

Before You Begin

Before You BeginBefore You Begin

Important – Please ReadImportant – Please Read

Important – Please Read

Important – Please ReadImportant – Please Read

Please read this installation section completely before installing the Maxtor hard drive. It gives general
information for installing a Maxtor hard drive in a typical computer system. If you don’t understand the
installation steps, have a qualified computer technician install the hard drive.

Back up. Protect your Existing DataBack up. Protect your Existing Data

Back up. Protect your Existing Data

Back up. Protect your Existing DataBack up. Protect your Existing Data

Periodic backup of important data is always a good idea. Whenever your computer is on, there is the
potential for losing data on your hard drive. This is especially true when running disk utilities or any software
that directly manipulates your files. Maxtor recommends that you make a backup copy of the files on any
existing hard drives prior to installing the new drive. If required, this data may then be copied to the Maxtor
hard drive after it has been installed in the computer. Refer to your computer user’s manual for detailed data
backup instructions.

Tools for InstallationTools for Installation

Tools for Installation

Tools for InstallationTools for Installation

The following tools are needed to install your new Maxtor hard drive:

• A small (#2) Phillips head screw driver

• Small needle-nose pliers or tweezers

• Your computer user’s manuals

• Operating system software

System RequirementsSystem Requirements

System Requirements

System RequirementsSystem Requirements

• IDE/AT interface
Maxtor recommends:

• Drives less than or equal to 8.4 GB – 486 DX 66 MHz

• Drives larger than 8.4 GB – Pentium-class processor

Operating System RequirementsOperating System Requirements

Operating System Requirements

Operating System RequirementsOperating System Requirements

• Drives less than or equal to 8.4 GB:

- DOS 5.0 or higher

• Drives larger than 8.4 GB:

- Installing as boot drive (Primary Master) requires full installation set of Windows 95/98 – not an update
from DOS or Windows 3.x.

- Installing as non-boot drive (Primary Slave, Secondary Master or Slave) requires Windows 95/98 on the
boot drive.

Hook upHook up

Hook up

Hook upHook up

Maxtor recommends that you use the MaxBlast™ Plus software to create a customized installation guide for your
system before physically installing your new hard drive. The information created by MaxBlast Plus relates to the
following illustrations.

Boot the System with the MaxBlast Plus DisketteBoot the System with the MaxBlast Plus Diskette

Boot the System with the MaxBlast Plus Diskette

Boot the System with the MaxBlast Plus DisketteBoot the System with the MaxBlast Plus Diskette

Before physically installing the Maxtor hard drive, boot your system with the MaxBlast Plus diskette. It will
assist you with the instructions in this section for a successful installation.

4 – 4

Configure the Drive JumpersConfigure the Drive Jumpers

Configure the Drive Jumpers

Configure the Drive JumpersConfigure the Drive Jumpers

The jumper configurations have three valid jumper settings – Master, Slave and Cable Select. Maxtor hard
drives are always shipped with the Master jumper setting enabled.

Install the 5.25-inch Mounting BracketsInstall the 5.25-inch Mounting Brackets

Install the 5.25-inch Mounting Brackets

Install the 5.25-inch Mounting BracketsInstall the 5.25-inch Mounting Brackets

If the Maxtor hard drive will be mounted in a 5.25-inch device bay, you will need to attach 5.25-inch
brackets to the hard drive. These brackets are not required if the drive is mounted in a 3.5-inch device bay.

Install the Hard Drive in a Device BayInstall the Hard Drive in a Device Bay

Install the Hard Drive in a Device Bay

Install the Hard Drive in a Device BayInstall the Hard Drive in a Device Bay

Refer to your computer user’s manual for specific mounting information. Be sure to secure the drive to the
device bay with all four screws.

Attach the Interface and Power CablesAttach the Interface and Power Cables

Attach the Interface and Power Cables

Attach the Interface and Power CablesAttach the Interface and Power Cables

Do not force or rock the connectors into their sockets on the hard drive. Push them in straight until they
are seated.

Note: A standard IDE cable can be used for drive installation; however, an Ultra ATA cable is required to
achieve Ultra ATA/100 data transfers in Ultra ATA/100 compatible systems. Follow the illustration below for
proper cable connections to the system and hard drive(s) when using this cable.

Attach an ATA interface connector to J1 on the Maxtor drive. Attach a power connector to J2 on the
Maxtor drive. This connector is keyed and will only fit one way. Check all other cable connections before
you power up. Striped/colored edge is pin 1

After attaching the ATA interface cable and the
power cable to the Maxtor hard drive, verify that
all other cables connected to other devices, the
mother board or interface card(s) are correctly
seated.

INSTALLATION

Striped/colored edge is pin

Figure 4 - 4

Start upStart up

Start up

Start upStart up

ATAInterface and Power Cabling

Turn your system ON. During the system start up sequence, run the SETUP (BIOS) program. Newer systems
usually display a message like “press DEL to enter Setup,” showing how to access the SETUP (BIOS) program.

Choose the device position where the Maxtor hard drive will be installed (Primary Master, Primary Slave,
Secondary Master, Secondary Slave or their equivalents) and select the “Auto Detect” option. Save and exit the
BIOS. The system will now boot. Boot to the MaxBlast™ Plus diskette.

Set upSet up

Set up

Set upSet up

MaxBlast Plus will guide you through the steps to prepare (partition and format) your new Maxtor hard drive.
Once you have completed this step, your new Maxtor hard drive will be ready to use.

Note: Do not discard the MaxBlast Plus diskette once the installation is complete. The diskette contains Maxdiag,
a diagnostic utility that is a separate program from the MaxBlast Plus installation software.

4 – 5

AT INTERFACE DESCRIPTION

SECTION 5

AA

T Interface DescriptionT Interface Description

A

T Interface Description

AA

T Interface DescriptionT Interface Description

Interface ConnectorInterface Connector

Interface Connector

Interface ConnectorInterface Connector

All Maxtor hard drives have a 40-pin ATA interface connector mounted on the PCBA. The drive may connect
directly to the host; or it can also accommodate a cable connection (maximum cable
length: 18 inches).

Figure 5-1

Data Connector

Pin Description SummaryPin Description Summary

Pin Description Summary

Pin Description SummaryPin Description Summary

PIN SIGN AL PIN SIGN AL

01 R e se t - 02 G round
03 DD7 04 DD8
05 DD6 06 DD9
07 DD5 08 DD10
09 DD4 10 DD11
11 DD3 12 DD12
13 DD2 14 DD13
15 DD1 16 DD14
17 DD0 18 DD15
19 Ground 20 (keypin)
21 DMARQ 22 Ground
23 DI OW -:S TOP 24 G round
25 DIOR -: H D M ARD Y:HS TROB E 26 G round
27 IORDY:D DMA RDY:DSTROBE 28 CSEL
29 D M AC K - 30 G ro und

31 INTRQ 32
33 DA 1 34 P D IAG -

35 DA0 36 DA2
37 C S 0 - 38 C S 1 ­39 D AS P - 40 G ro und

IOCS16

Obsolete

5 – 1

AT INTERFACE DESCRIPTION

Pin Description TablePin Description Table

Pin Description Table

Pin Description TablePin Description Table

PIN NAME PIN I/O SIGNAL NAME SIGNAL DESC RIPTIO N

RESET - 01 I Host Reset Reset signal from the host system. Active during power up and inactive after.

DD0 17 I/O Host Data Bus 16 bit bi-directional data bus between host and drive. Lower 8 bits used for

DD1 15 I/O
DD2 13 I/O
DD3 11 I/O
DD4 09 I/O
DD5 07 I/O
DD6 05 I/O
DD7 03 I/O
DD8 04 I/O

DD9 06 I/O
DD10 08 I/O
DD11 10 I/O
DD12 12 I/O
DD13 14 I/O
DD14 16 I/O
DD15 18 I/O

D MARQ 21 O DMA Request Th is si gnal i s used wi th DMAC K fo r DMA transfers . B y asser ting this s ig nal, the

DIOW -

STOP

DIOR -

HDMA RDY

-

HSTROBE

IORDY

DDMA RDY

-

DSTROBE

CSEL 28 C able Se lect Us ed fo r Mas ter/Slave se lection via ca ble. Req uires special cab ling o n host

DMACK - 29 I D MA Acknowledge This signal is used with DMARQ for DMA transfers . By asserting this signal, the

INT RQ 31 O H os t Int er rup t

IOCS16 32 Device 16 bit I/O Obsolete

PDIAG - 34 I/O Passed Di agnostic Output by drive when in Slave mode; Input to drive when in Master mode.

DA0 35 I Host Address Bus 3 bit binary address from the host to select a register in the drive.

DA1 33 I

DA2 36 I
CS 0 - 37 I Ho st Ch ip Se lect 0 Chip select fro m the host used to a ccess the Command Block reg i sters i n the

CS 1 - 38 I Host Chip S e lect 1 Chip sele ct from the host used to acce ss the Co ntrol registe rs in the d rive. This

DASP - 39 I/O Dri ve Active/D rive

GND 02 N/A Ground Signal ground.

K EY 20 N/ A Key Pi n used for k eying the i nterf ace connec t or .

register and ECC byte transfers. All 16 bits us ed for data transfers.

drive indi ca tes that data is r eady to be transfer ed to a nd from t he h ost.

23 I Host I/O Write Rising edge of Write strobe clocks data from the host data bus to a register on

25 I Host I/O Read Read strobe enables data from a register on the drive onto the host data bus.

27 O I/O Channel Ready This signal may be driven low by the drive to insert wait states into host I/O

Request

1 Present

19
22
24
26
30
40

the drive.

DMA ready during UltraDMA data in bursts.
Data strobe during UltraDMA data out bursts.

cycles.
DMA ready during UltraDMA data out bursts.
Data strobe during UltraDMA data in bursts.

system and installation of Cable Select jumper.

host is acknowledging the receipt of data or is indicating that data is available.
Interrupt to the host asserted when the drive requires attention from the host.

dr ive. This signa l i s a d ecode of I /O addres s es 1F0 - 1F 7 hex.

signal is a decode of I/O addresses 3F6 - 3F7 hex.
Time-multiplexed, open collector output which indicates that a drive is active, or

that
device 1 is present.

5 – 2

PIO TimingPIO Timing

PIO Timing

PIO TimingPIO Timing

TIMING PARAMET ERS MODE 0 MODE 1 MODE 2 MODE 3 MODE 4

t0 Cy cle Ti me ( min ) 6 00 ns 3 83 ns 2 4 0 ns 18 0 ns 1 2 0 ns
t1 Address valid to DIOR-/DIOW - setup (min) 70 ns 50 ns 30 ns 30 ns 25 ns
t2 D IOR- /D IOW- 16 - bi t (m in) 1 6 5 ns 1 2 5 ns 1 0 0 ns 8 0 ns 7 0 ns
t2 i D IOR-/DIOW- recove ry time (min ) 70 ns 25 ns
t3 DIOW- data setup (min) 60 ns 45 ns 30 ns 30 ns 20 ns
t4 DIO W- da t a ho ld ( mi n) 3 0 ns 2 0 ns 1 5 ns 1 0 ns 1 0 ns
t5 D IOR- data setup (min) 50 ns 35 ns 20 ns 20 ns 20 ns
t6 DIO W- da ta hold ( min ) 5 ns 5 ns 5 ns 5 ns 5 ns
t6Z DIOR- data tristate (max) 30 ns 30 ns 30 ns 30 ns 30 ns
t9 D IOR-/DIOW- to address valid hold (min) 20 ns 15 ns 10 ns 10 ns 10 ns
tRd Read Data Valid to IORDY a ctive (min) 0 0 0 0 0
tA IORDY Setup Time 35 ns 35 ns 35 ns 35 ns 35 ns
tB IORDY Pulse Width (max) 1250 ns 1250 ns 1250 ns 12 50 ns 12 50 ns

AT INTERFACE DESCRIPTION

Figure 5 - 2

PIO Data Transfer To/From Device

5 – 3

AT INTERFACE DESCRIPTION

DMA TimingDMA Timing

DMA Timing

DMA TimingDMA Timing

T IMIN G PARAMETE RS MODE 0 MODE 1 MODE 2

t0 Cycle Ti me (min) 480 ns 150 ns 120 ns
tC DMACK to DMARQ d elay
tD DIOR-/DIOW- (min) 215 ns 80 ns 70 ns
tE DIOR- data access (min) 1 50 ns 6 0 ns
tF DIOR - d ata ho ld ( min ) 5 ns 5 ns 5 ns
tG DIOR-/DIOW- data setup (min) 100 ns 30 ns 20 ns
tH DIO W- d ata ho ld ( min ) 2 0 ns 1 5 ns 1 0 ns
tI DM AC K to DIOR-/D IOW- se tup (min) 0 0 0
tJ D IOR-/ DIOW- to D M ACK hold (min) 2 0 ns 5 ns 5 ns
tK r DIO R- neg a ted p uls e wi dt h ( min ) 5 0 ns 5 0 ns 2 5 ns
tKw D IOW- negated puls e width (min) 215 ns 50 ns 25 ns
tL r DIOR - to DM A RQ del ay (ma x ) 1 2 0 ns 4 0 ns 3 5 ns
tLw DIO W- to D MA RQ de la y (max ) 4 0 ns 4 0 ns 3 5 ns
tZ DMA C K - t o tr ist a te (m ax ) 2 0 ns 2 5 ns 25 ns

5 – 4

Multi-word DMA Data Transfer

Figure 5 - 3

AT INTERFACE DESCRIPTION

g

y g

y

y

g

g

Ultra DMA TimingUltra DMA Timing

Ultra DMA Timing

Ultra DMA TimingUltra DMA Timing

TIM ING PARAMET ERS

t

Cycle Ti me (from S TROBE edge to STROBE edge) 112 73 54 39 25 16.8

CYC

Two cycle ti me (from rising edge to next ris ing edge or

t2

CYC

from falling edge to next falling edge of STROBE)

t

Da ta setup time (at recipient) 15 10 7 7 5 4

DS

t

Data hold time (at recipie nt) 5 5 5 5 5 4.6

DH

t

Data valid setup time at sender (time from data bus bein

DVS

valid unt il STROBE edge)

Data valid hold time a t sender (time from STROBE edge

t

DVH

until data ma

t

First STROBE (tim e for device to send fi rst STROBE) 0 230 0 2 00 0 1 70 0 130 0 120 0 90

FS

Limited interlock time (time allowed between an action b

t

LI

one agent, either host or device, and the following acti o n

the other agent)

b

t

Interloc k t ime wi th minimum 20 20 20 20 20 20

ML I

t

Unlimited interlock time 000000

UI

t

Maximum ti me al lowed fo r outputs to rel ease 10 10 10 10 10 10

AZ

t

ZAH

Mini mum delay time required for output drivers turning on
(from rele ased state )

t

ZAD

t

En velop e time (all contro l s ignal transitions are within the

ENV

DMACK envelope by this much time)
STROBE to DMARDY (re sponse time to ensure the

t

SR

synchronous pause case when the recipient is pausing)
Ready-to-final -STROBE time (no more STROBE edges

t

RFS

may be sent thi s long after receiving DMARDY- negation)
Ready-to-pause time (time until a recipient may assume

t

RP

that the sender has paused after ne

t

Pull-up time before allowing IORD Y t o be re le as ed 20 20 20 20 20 20

IORDYZ

t

Minimum time device shall wait before driving IORDY000000

ZIORDY

t

Setup and hold times before assertion and negation of

ACK

DMACK-

Time from STROBE edge to STOP assertion when the

t

SS

sender is stoppin

(all times in nanoseconds)

o inva li d)

ation of DMARDY-)

MODE 0 MODE 1 MODE 2 MODE 3 MODE 4 MODE 5

MIN MAX MIN MAX MIN MAX MIN MAX MIN MAX MIN MAX

230 153 115 86 57 38

70 48 31 20 6.7 4.8

6.2 6.2 6.2 6.2 6.2 4.8

0 150 0 150 0 150 0 100 0 100 0 75

20 20 20 20 20 20

000000

20 70 20 70 20 70 20 55 20 55 20 50

50 30 20 NA NA NA

75 70 60 60 60 50

160 125 100 100 100 85

20 20 20 20 20 20

50 50 50 50 50 50

DMARQ

(device)

DMACK-

(host)

STOP
(host)

HDMARDY-

(host)

DSTROBE

(device)

DD(15:0)

DA0, DA1, DA2,

CS0-, CS1-

t

UI

t

ACK

t

ACK

t

ZIORDY

t

t

ACK

t

ENV

t

ENV

t

AZ

Figure 5 - 4

Initiating an Ultra DMA Data In Burst

t

ZAD

ZAD

t

FS

t

FS

t

VDS

t

DVH

5 – 5

AT INTERFACE DESCRIPTION

DSTROBE

at device

DD(15:0)

at device

DSTROBE

at host

t

DVH

t

CYC

t

DVS

t

2CYC

t

DVH

t

CYC

t

DVS

t

DVH

t

2CYC

DD(15:0)

at host

DMARQ
(device)

DMACK-

HDMARDY-

DSTROBE

DD(15:0)

(host)
STOP

(host)

(host)

(device)

(device)

t

DH

t

DS

t

DH

t

DS

t

DH

Figure 5 - 5

Sustained Ultra DMA Data In Burst

t

RP

t

SR

t

RFS

5 – 6

Host Pausing an Ultra DMA Data In Burst

Figure 5 - 6

DMARQ

(

)

(

)

(

)

device

DMACK-

(host)

STOP
(host)

HDMARDY-

(host)

DSTROBE

device

DD(15:0)

DA0, DA1, DA2,

CS0-, CS1-

AT INTERFACE DESCRIPTION

t

MLI

t

t

ACK

ACK

t

t

IORDYZ

DVH

t

LI

t

LI

t

SS

t

ZAH

t

AZ

t

LI

t

DVS

CRC

t

ACK

DMARQ

(device)

DMACK-

(host)

STOP

host

HDMARDY-

(host)

DSTROBE

(device)

DD(15:0)

t

RFS

Device Terminating an Ultra DMA Data In Burst

Figure 5 - 7

t

LI

t

ZAH

t

t

RP

AZ

t

LI

t

MLI

t

ACK

t

ACK

t

t

MLI

DVS

t

IORDYZ

t

DVH

CRC

t

ACK

DA0, DA1, DA2,

CS0-, CS1-

Figure 5 - 8

Host Terminating an Ultra DMA Data In Burst

5 – 7

AT INTERFACE DESCRIPTION

(

)

DMARQ

(device)

DMACK-

host

t

UI

STOP
(host)

DDMARDY-

(device)

HSTROBE

(host)

DD(15:0)

(host)

DA0, DA1, DA2,

CS0-, CS1-

HSTROBE

at host

DD(15:0)

at host

t

DVH

t

t

t

ACK

ACK

ACK

t

ZIORDY

t

ENV

Figure 5 - 9

Initiating an Ultra DMA Data Out Burst

t

2CYC

t

CYC

t

t

DVS

DVH

t

CYC

t

LI

t

t

DVS

DVS

t

UI

t

DVH

t

2CYC

t

DVH

HSTROBE

at device

t

DH

t

DS

t

DH

t

DS

t

DH

DD(15:0)
at device

Figure 5 - 10

Sustained Ultra DMA Data Out Burst

5 – 8

DMARQ

(device)

DMACK-

(host)

STOP

(host)

DDMARDY-

(device)

HSTROBE

(host)

DD(15:0)

(host)

AT INTERFACE DESCRIPTION

t

RP

t

SR

t

RFS

DMARQ
(device)

DMACK-

(host)

STOP

(host)

DDMARDY-

(device)

HSTROBE

(host)

DD(15:0)

(host)

DA0, DA1, DA2,

CS0-, CS1-

Device Pausing an Ultra DMA Data Out Burst

Figure 5 - 11

t

LI

t

MLI

t

t

SS

t

LI

LI

t

DVS

CRC

t

t

ACK

t

ACK

t

ACK

IORDYZ

t

DVH

Host Terminating an Ultra DMA Data Out Burst

Figure 5 - 12

5 – 9

AT INTERFACE DESCRIPTION

(

)

(

)

,

DMARQ

(device)

DMACK-

(host)

STOP

host

DDMARDY-

device

HSTROBE

(host)

DD(15:0)

(host)

DA0, DA1, DA2,

CS0-

CS1-

t

MLI

t

MLI

t

RFS

t

LI

t

RP

t

LI

Figure 5 - 13

Device Terminating an Ultra DMA Data Out Burst

t

ACK

t

IORDYZ

t

ACK

t

DVS

t

DVH

CRC

t

ACK

5 – 10

HOST SOFTWARE INTERFACE

SECTION 6

Host Software InterfaceHost Software Interface

Host Software Interface

Host Software InterfaceHost Software Interface

The host communicates with the drive through a set of controller registers accessed via the host’s I/O ports.
These registers divide into two groups: the Task File, used for passing commands and command parameters and
the Control/Diagnostic registers.

Task File RegistersTask File Registers

Task File Registers

Task File RegistersTask File Registers

The Task File consists of eight registers used to control fixed disk operations. The host accesses each register
by the I/O port address shown in this Task File register map:

I/O POR T RE AD WR ITE

1F0 h Da ta Regi ster Data Reg ister
1F1h Error Register Features Reg ister
1F2h Sector Count Sector Count
1F3h Sector Number Sector Number
1F4h C ylinder Low Cylinder Low
1F5h C ylinder High Cylinder High
1F6h Drive/Head (SDH) Drive/Head (SDH)
1F7h Status Register Command Register

Data RegisterData Register

Data Register

Data RegisterData Register

Provides access to the drive’s sector buffer for read and write operations. With the exception of ECC byte
transfers (which, during Read long and Write long commands, are 8 bits wide), data transfers through the
Data register are all 16 bits wide.

Error RegisterError Register

Error Register

Error RegisterError Register

A read-only register containing specific information regarding the previous command. Data interpretation
differs depending on whether the controller is in operational or diagnostic mode. A power up, reset,
software reset, or receipt of a diagnostic command sets the controller into diagnostic mode. This mode
invalidates contents of the Status register. The contents of the Error register reflect a completion code.

Issuing any command (apart from a Diagnostic command) places the controller into operational mode.
In operational mode, the Error register is valid only when the Error bit in the Status register is set. The bit
definitions for operational mode follow:

76543210
0 ECC 0 IDNF 0 ABRT TK0 AMNF

Interface

CRC

Data

ECC Error

Not

Used

ID

Not F ound

Not

Used

Aborted

Comma nd

Track 0

Error

Address

Mark Not

Found

Interface CRC – An interface CRC error occurred during an Ultra DMA transfer.

Data ECC Error – An non-correctable ECC error occurred during a Read Sector command.

Firmware Problem – Indicates a firmware problem was detected, (e.g., invalid interrupt, divide overflow).

ID Not Found – Either a matching ID field not found, or a CRC error occurred.

Aborted Command – Invalid commands, write fault, no seek complete, or drive not ready.

Track 0 Error – Track 0 was not found during execution of a Restore command.

Address Mark Not Found – The Address Mark could not be found after an ID match.

Features RegisterFeatures Register

Features Register

Features RegisterFeatures Register

Enables or disables features through the Set Features command.

6 – 1

HOST SOFTWARE INTERFACE

Sector Count RegisterSector Count Register

Sector Count Register

Sector Count RegisterSector Count Register

Holds the number of sectors to be sent during a Read or Write command, and the number of sectors per
track during a Format command. A value of zero in this register implies a transfer of 256 sectors. A multi­sector operation decrements the Sector Count register. If an error occurs during such an operation, this
register contains the remaining number of sectors to be transferred.

Sector Number RegisterSector Number Register

Sector Number Register

Sector Number RegisterSector Number Register

Holds the starting sector number for any disk operation. The register is updated as each sector is processed in
a multi-sector operation.

Cylinder Number RegistersCylinder Number Registers

Cylinder Number Registers

Cylinder Number RegistersCylinder Number Registers

Two 8-bit Cylinder Number registers (Low and High) specify the starting cylinder for disk operation.

Device/Head RegisterDevice/Head Register

Device/Head Register

Device/Head RegisterDevice/Head Register

Used to specify the drive and head number to be operated on during any disk operations. Within the
context of a Set Parameters command, this register specifies the maximum number of heads on the drive.
Bit definitions follow:

76543210
1 LB A 1 DRV HS3 HS2 HS 1 HS 0

LBA

Mode

Dri ve

Select

Head

Select

Head

Select

Head

Select

Head

Select

Select LBA Mode

the Task File register contents are defined as follows for the Read/Write and translate command:

CONT EN TS LBA BITS

Sector Number 0 - 7
Cyl inder Lo w 8 - 15
Cylinder High 16 - 23
Dri ve/Head 24 - 27

– Enabling this bit for commands not supported by LBA mode will abort the selected command. When set,

Drive Select – Set to 0 to select the master drive; set to 1 to select the slave drive.

Head Select – Specifies the binary coded address of the head to be selected.

Status RegisterStatus Register

Status Register

Status RegisterStatus Register

Contains results of the last command executed, and the drive’s status. The other seven Task File registers may
be read only when bit 7 (BUSY) of the Status register is low. Reading any of the Task File registers when
BUSY is high returns the value of the Status register. Reading the Status register also clears any interrupt
request to the host. Bit definitions follow:

7654 3210
BUSY D RDY DF D SC DRQ 0 0 E RR
Controller

Busy

Device
Ready

Device
Fault

Device
Seek
Complete

Data
Request

Error

Controller Busy – Goes active when a command is written to the Command register, indicating controller
task execution. After a command, this bit resets.

Device Ready – Indicates that the drive is ready for commands. If drive ready is not present, all commands abort.

Device Fault – Indicates the drive’s detection of a write fault condition, causing all commands to abort.

Device Seek Complete – Signifies a seek completion, and that the drive is on track.

Data Request – Indicates that the drive’s sector buffer is ready for data transfer.

6 – 2

Error – The Error bit sets when the previous command has completed with a non-recoverable error.

HOST SOFTWARE INTERFACE

Command RegisterCommand Register

Command Register

Command RegisterCommand Register

Contains code for the command to be performed. Additional command information should be written to the
task file before the Command register is loaded. When this register is written, the BUSY bit in the Status
register sets, and interrupt request to the host clears; invalid commands abort. (Detailed information on interface
commands is given in Section 7.) Hex values for valid command formats follow:

Read CommandsRead Commands

Read Commands

Read CommandsRead Commands

Read Sector(s) 20h Normal reads; retries enabled

21h Normal reads; retries disabled
22h Read Long; retries enabled
23h Read Long; retries disabled

Read Verify Sector(s) 40h Retries enabled

41h Retries disabled
Read Sector Buffer E4h
Read Multiple C4h
Read DMA C8h

C9h No retries

Write CommandsWrite Commands

Write Commands

Write CommandsWrite Commands

Write Sector(s) 30h Normal writes; retries enabled

31h Normal writes; retries disabled

32h Write Long; retries enabled

33h Write Long; retries disabled
Write Verify Sector(s) 3Ch
Write Sector Buffer E8h
Write Multiple C5h
Write DMA CAh

CBh No retries

Mode Set/Check CommandsMode Set/Check Commands

Mode Set/Check Commands

Mode Set/Check CommandsMode Set/Check Commands

Set Features EFh
Set Multiple Mode C6h
Read Native Max Address F8h
Set Max Mode F9h

Power Mode CommandsPower Mode Commands

Power Mode Commands

Power Mode CommandsPower Mode Commands

Standby Immediate 94/E0h Stops drive spindle; do not change time-out value
Idle Immediate 95/E1h Starts spindle; do not change time-out value
Standby 96/E2h Stops spindle; change time-out value
Idle 97/E3h Starts spindle; change time-out value
Check Power Mode 98/E5h
Set Sleep Mode 99/E6h

Initialization CommandsInitialization Commands

Initialization Commands

Initialization CommandsInitialization Commands

Identify Drive ECh
Initialize Drive Parameters 91h
Re-calibrate 1xh

Seek, Format, and Diagnostic CommandsSeek, Format, and Diagnostic Commands

Seek, Format, and Diagnostic Commands

Seek, Format, and Diagnostic CommandsSeek, Format, and Diagnostic Commands

Seek 7xh
Format Track 50h
Execute Drive Diagnostic 90h

S.M.A.R.T. CommandsS.M.A.R.T. Commands

S.M.A.R.T. Commands

S.M.A.R.T. CommandsS.M.A.R.T. Commands

Execute S.M.A.R.T. B0h

6 – 3

HOST SOFTWARE INTERFACE

y

y

g

y

SummarySummary

Summary

SummarySummary

CO M M AN D N A ME C O M MA ND C OD E PA RA ME T E R S U S E D

Recalibrate 0001xxxx NNNN D
Read Sector(s) 0 0 1 0 0 0 L x N Y Y Y Y
Read D MA 1 1 0 0 1 0 0 x N Y Y Y Y
Write Sector(s) 0 0 1 1 0 0 L x N Y Y Y Y
Write DMA 1100101x NYYY Y
Write Verif
Read Verif
Format Track 010 10 0 0 0 NNNY Y
Seek 0 1 1 1 x x x x N N Y Y Y
Execute D ia
Initialize P a rame ters 1 0 0 1 0 0 0 1 N Y N N Y
Rea d S e ctor B uffe r 1 1 1 0 0 1 0 0 N N N N D
W rite S e c tor B uffe r 1 1 1 0 1 0 0 0 N N N N D
Id e ntif
Set Features 1110 1111 YNNN D
Read Multiple 1 1 0 0 0 1 0 0 N Y Y Y Y
Write Multip le 1 1 0 0 0 1 0 1 N Y Y Y Y
Set Multiple Mode 1 1 0 0 0 1 1 0 N Y N N D
Read Native M ax Ad dress 1 1 1 1 1 0 0 0 N N N N Y
Set Max 11111001 NYYY Y

Sector(s) 00 111100 NYYY Y
Sector(s) 0100000x NYYY Y

Drive 11 10 1 1 0 0 NNNN D

b7 b6 b5 b4 b3 b2 b1 b0 F S C SN C SD H

nostic 10010000 NNNN D

6 – 4

HOST SOFTWARE INTERFACE

Control Diagnostic RegistersControl Diagnostic Registers

Control Diagnostic Registers

Control Diagnostic RegistersControl Diagnostic Registers

These I/O port addresses reference three Control/Diagnostic registers:

I/O POR T R EAD WRITE

3F6h Alternate Status Fixed Disk Control
3F7h Digital Input Not used

Alternate Status RegisterAlternate Status Register

Alternate Status Register

Alternate Status RegisterAlternate Status Register

Contains the same information as the Status register in the Task File. However, this register may be read at
any time without clearing a pending interrupt.

Device Control RegisterDevice Control Register

Device Control Register

Device Control RegisterDevice Control Register

Contains the software Reset and Enable bit to enable interrupt requests to the host. Bit definitions follow:

76543210
00000SRSTIEN0

Reset IR Q En ab le

Reset – Setting the software Reset bit holds the drive in the reset state. Clearing the bit re-enables the drive.
The software Reset bit must be held active for a minimum of 5 µsec.

IRQ Enable – Setting the Interrupt Request Enable to 0 enables the IRQ 14 signal to the host. When this

bit is set to 1, IRQ14 is tri-stated, and interrupts to the host are disabled. Any pending interrupt occurs when

the bit is set to 0. The default state of this bit after power up is 0 (interrupt enabled).

Digital Input RegisterDigital Input Register

Digital Input Register

Digital Input RegisterDigital Input Register

Contains information about the state of the drive. Bit definitions follow:

76543210
x -WG -HS3 -HS2 -HS1 -HS0 -DS1 DS0

Reserved Write

Gate

Head

Select 3

Head

Select 2

Head

Select 1

Head

Select 0

Drive

Select 1

Drive

Select 0

Bit 7 of the host data bus is not driven when this register is read.

-Write Gate – Reflects the state of the active low write gate signal on the drive.

-Head Select 3 through -Head Select 0 – Represents the ones complement of the currently selected head number.

-Drive Select 1 – Is 0 if drive 1 selected; 1 otherwise.

-Drive Select 0 – Is 0 if drive 0 selected; 1 otherwise.

6 – 5

HOST SOFTWARE INTERFACE

Reset and Interrupt HandlingReset and Interrupt Handling

Reset and Interrupt Handling

Reset and Interrupt HandlingReset and Interrupt Handling

Reset HandlingReset Handling

Reset Handling

Reset HandlingReset Handling

One of three different conditions may cause a reset: power on, hardware reset or software reset. All three
cause the interface processor to initialize itself and the Task File registers of the interface. A reset also causes a
set of the Busy bit in the Status register. The Busy bit does not clear until the reset clears and the drive
completes initialization. Completion of a reset operation does not generate a host interrupt.

Task File registers are initialized as follows:

Error 1

Sector Count 1

Sector Number 1

Cylinder Low 0

Cylinder High 0

Drive/Head 0

Interrupt HandlingInterrupt Handling

Interrupt Handling

Interrupt HandlingInterrupt Handling

The drive requests data transfers to and from the host by asserting its IRQ 14 signal. This signal interrupts the
host if enabled by bit 1 (IRQ enable) of the Fixed Disk Control register.

Clear this interrupt by reading the Status register, writing the Command register, or by executing a host
hardware or software reset.

6 – 6

Interface CommandsInterface Commands

Interface Commands

Interface CommandsInterface Commands

The following section describes the commands (and any parameters necessary to execute them),
as well as Status and Error register bits affected.

Read CommandsRead Commands

Read Commands

Read CommandsRead Commands

Read Sector(s)
Read Verify Sector(s)
Read Sector Buffer
Read DMA

Multi-word DMA

Ultra DMA
Read Multiple
Set Multiple

Write CommandsWrite Commands

Write Commands

Write CommandsWrite Commands

Write Sector(s)
Write Verify Sector(s)
Write Sector Buffer
Write DMA

Multi-word DMA

Ultra DMA
Write Multiple

INTERFACE COMMANDS

SECTION 7

Mode Set/Check CommandsMode Set/Check Commands

Mode Set/Check Commands

Mode Set/Check CommandsMode Set/Check Commands

Set Features Mode
Set Multiple Mode
Set Max Mode
Read Native Max Address

Power Mode CommandsPower Mode Commands

Power Mode Commands

Power Mode CommandsPower Mode Commands

Standby Immediate
Idle Immediate
Standby
Idle
Check Power Mode
Set Sleep Mode

Initialization CommandsInitialization Commands

Initialization Commands

Initialization CommandsInitialization Commands

Identify Drive
Initialize Drive Parameters
S.M.A.R.T.

7 – 1

INTERFACE COMMANDS

Read CommandsRead Commands

Read Commands

Read CommandsRead Commands

Read Sector(s)Read Sector(s)

Read Sector(s)

Read Sector(s)Read Sector(s)

Reads from 1 to 256 sectors, as specified in the Command Block, beginning at the specified sector. (A sector
count of 0 requests 256 sectors.) Immediately after the Command register is written, the drive sets the BSY
bit and begins execution of the command. If the drive is not already on the desired track, an implied seek is
performed.

Once at the desired track, the drive searches for the data address mark of the requested sector. The data
address mark must be recognized within a specified number of bytes, or the Data Address Mark Not Found
error will be reported. Assuming the data address mark is found:

1. The data field is read into the sector buffer.

2. Error bits are set (if an error was encountered).

3. The DRQ bit is set.

4. An interrupt is generated.

The DRQ bit is always set, regardless of the presence or absence of an error condition after the sector.
Upon command completion, the Command Block registers contain the numbers of the cylinder, head and
sector of the last sector read. Back-to-back sector read commands set DRQ and generate an interrupt when
the sector buffer is filled at the completion of each sector. The drive is then ready for the data to be read by
the host. DRQ is reset and BSY is set immediately when the host empties the sector buffer.

If an error occurs during Read Sector commands, the read terminates at the sector where the error occurred.
The host may then read the Command Block to determine the nature of that error, and the sector where it
happened. If the error type is a correctable or an non-correctable data error, the flawed data is loaded into
the sector buffer.

A Read Long command sets the Long bit in the command code and returns the data and the ECC bytes in
the data field of the specified sector. During a Read Long, the drive does not check the ECC bytes to
determine if there has been a data error. The Read Long command is limited to single sector requests.

Read Verify Sector(s)Read Verify Sector(s)

Read Verify Sector(s)

Read Verify Sector(s)Read Verify Sector(s)

Identical to the Read Sector(s) command, except that:

1. DRQ is never set,

2. No data is transferred back to the host and

3. The long bit is not valid.

7 – 2

INTERFACE COMMANDS

Read DMARead DMA

Read DMA

Read DMARead DMA

Multi-word DMA

Identical to the Read Sector(s) command, except that

1. The host initializes a slave-DMA channel prior to issuing the command,

2. Data transfers are qualified by DMARQ and are performed by the slave-DMA channel
and

3. The drive issues only one interrupt per command to indicate that data transfer has
terminated and status is available.

Ultra DMA

With the Ultra DMA Read protocol, the control signal (DSTROBE) that latches data from DD(15:0) is
generated by the devices which drives the data onto the bus. Ownership of DD(15:0) and this data strobe
signal are given DSTROBE to the drive during an Ultra DMA data in burst.

During an Ultra DMA Read burst, the drive always moves data onto the bus, and, after a sufficient time to
allow for propagation delay, cable settling, and setup time, the sender shall generate a DSTROBE edge to
latch the data. Both edges of DSTROBE are used for data transfers.

Any unrecoverable error encountered during execution of a Read DMA command terminates data transfer
after the transfer of all sectors prior to the sector where the error was detected. The sector in error is not
transferred. The drive generates an interrupt to indicate that data transfer has terminated and status is
available. The error posting is identical to the Read Sector(s) command.

Read MultipleRead Multiple

Read Multiple

Read MultipleRead Multiple

Performs similarly to the Read Sector(s) command, except that for each READ MULTIPLE command data
transfers are multiple sector blocks and the Long bit is not valid.

Execution is also similar to that of the READ SECTOR(S) command, except that:

1. Several sectors are transferred to the host as a block, without intervening interrupts.

2. DRQ qualification of the transfer is required only at the start of each block, not of each sector.

The block count consists of the number of sectors to be transferred as a block. (The block count is
programmed by the Set Multiple Mode command, which must be executed prior to the Read Multiple
command.) READ LONG command is limited to single sector requests.

When the Read Multiple command is issued, the Sector Count register contains the number of sectors
requested — not the number of blocks or the block count. If the number of sectors is not evenly divisible
by the block count, as many full blocks as possible are transferred, followed by a final, partial block transfer.
This final, partial block transfer is for N sectors, where N = (sector count) modulo (block count)

The Read Multiple operation will be rejected with an Aborted Command error if attempted:

1. Before the Set Multiple Mode command has been executed, or

2. When Read Multiple commands are disabled.

The controller reports disk errors encountered during Read Multiple commands at the start of the block or
partial block transfer. However, DRQ still sets, and the transfer occurs normally, along with the transfer of
any corrupt data. Remaining block data from the following the sector in error is not valid.

If the Sector Count register contains 0 when the Set Multiple Mode command is issued, Read Multiple and
Write Multiple commands are disabled; no error is returned. Once the appropriate action has been taken, the
controller resets BSY and generates an interrupt. At power up, or after a hardware or software reset, Read
Multiple and Write Multiple commands are disabled by default.

7 – 3

INTERFACE COMMANDS

Set Multiple ModeSet Multiple Mode

Set Multiple Mode

Set Multiple ModeSet Multiple Mode

Enables the controller to perform Read and Write Multiple operations, and establishes the block count for
these commands. Before issuing this command, the Sector Count register should be loaded with the number
of sectors per block. The drives support block sizes of 2, 4, 8 and 16 sectors.

When this command is received, the controller sets BSY and examines the Sector Count register contents. If
they contain a valid and supported block count value, that value is loaded for all subsequent Read and Write
Multiple commands, and execution of those commands is enabled. An invalid and unsupported block count
in the register results in an Aborted Command error and disallows Read Multiple and Write Multiple
commands.

Write CommandsWrite Commands

Write Commands

Write CommandsWrite Commands

Write Sector(s)Write Sector(s)

Write Sector(s)

Write Sector(s)Write Sector(s)

Writes from 1 to 256 sectors, beginning at a sector specified in the Command Block. (A sector count of 0
requests 256 sectors.)

When the Command register is written, the drive sets the DRQ bit and waits for the host to fill the sector
buffer with the data to be written. An interrupt is not generated to start the first buffer fill operation.

Once the buffer is full, the drive resets DRQ, sets BSY, and begins command execution. If the drive is not
already on the desired track, an implied seek is performed.

The data loaded in the buffer is written to the data field of the sector, followed by the ECC bytes. Upon
command completion, the Command Block registers contain the cylinder, head and sector number of the
last sector written. The next time the buffer is ready to be filled during back-to-back Write Sector
commands, DRQ is set and an interrupt is generated.

After the host fills the buffer, DRQ is reset and BSY is set. If an error occurs, Write Sector operations
terminate at the sector containing the error.

The Command Block registers then contain the numbers of the cylinder, head and sector where the error
occurred. The host may read the Command Block to determine the nature of that error, and on which
sector it happened. A Write Long may be executed by setting the Long bit in the command code. The
Write Long command writes the data and the ECC bytes directly from the sector buffer; the drive itself does
not generate the ECC bytes. Restrict Write Long commands to PIO Mode 0.

Write Verify Sector(s)Write Verify Sector(s)

Write Verify Sector(s)

Write Verify Sector(s)Write Verify Sector(s)

Identical to the Write Sector(s) command, except that the requested sectors are verified immediately after
being written. The verify operation reads (without transferring), and checks for data errors. Any errors
encountered during this operation are reported.

Write Sector BufferWrite Sector Buffer

Write Sector Buffer

Write Sector BufferWrite Sector Buffer

Allows the host to overwrite the contents of the drive’s sector buffer with a selected data pattern. When this
command is received, the drive:

1. Sets BSY,

2. Sets up the sector buffer for a write operation,

3. Sets DRQ,

4. Resets BSY and

5. Generates an interrupt.

7 – 4

The host may then write up to 256 words of data to the buffer. A disk write task begins to store the host
data to disk. Host write commands continue to be accepted and data transferred to the buffer until either
the write command stack is full or the data buffer is full. The drive may reorder write commands to optimize
drive throughput.

INTERFACE COMMANDS

Write MultipleWrite Multiple

Write Multiple

Write MultipleWrite Multiple

Performs similarly to the Write Sector(s) command, except that:

1. The controller sets BSY immediately upon receipt of the command,

2. Data transfers are multiple sector blocks and

3. The Long bit and Retry bit is not valid.

Command execution differs from Write Sector(s) because:

1. Several sectors transfer to the host as a block without intervening interrupts.

2. DRQ qualification of the transfer is required at the start of the block, not on each sector.

The block count consists of the number of sectors to be transferred as a block and is programmed by the Set
Multiple Mode command, which must be executed prior to the Write Multiple command. When the Write
Multiple command is issued, the Sector Count register contains the number of sectors requested — not the
number of blocks or the block count.

If the number of sectors is not evenly divisible by the block count, as many full blocks as possible are
transferred, followed by a final, partial block transfer. This final, partial block transfer is for N sectors, where
N = (sector count) modulo (block count)

The Write Multiple operation will be rejected with an Aborted Command error if attempted:

1. Before the Set Multiple Mode command has been executed, or

2. When Write Multiple commands are disabled.

All disk errors encountered during Write Multiple commands report after the attempted disk write of the
block or partial block in which the error occurred.

The write operation ends with the sector in error, even if it was in the middle of a block. When an error
occurs, subsequent blocks are not transferred. When DRQ is set at the beginning of each full and partial
block, interrupts are generated.

Write DMAWrite DMA

Write DMA

Write DMAWrite DMA

Multi-word DMA

Identical to the Write Sector(s) command, except that:

1. The host initializes a slave-DMA channel prior to issuing the command,

2. Data transfers are qualified by DMARQ and are performed by the slave-DMA channel and

3. The drive issues only one interrupt per command to indicate that data transfer has terminated
at status is available.

Ultra DMA

With the Ultra DMA Write protocol, the control signal (HSTROBE) that latches data from DD(15:0) is
generated by the devices which drives the data onto the bus. Ownership of DD(15:0) and this data
strobe signal are given to the host for an Ultra DMA data out burst.

During an Ultra DMA Write burst, the host always moves data onto the bus, and, after a sufficient time to
allow for propagation delay, cable settling, and setup time, the sender shall generate a HSTROBE edge to
latch the data. Both edges of HSTROBE are used for data transfers.

Any error encountered during Write DMA execution results in the termination of data transfer. The drive
issues an interrupt to indicate that data transfer has terminated and status is available in the error register.
The error posting is the same as that of the Write Sector(s) command.

7 – 5

INTERFACE COMMANDS

Mode Set/Check CommandsMode Set/Check Commands

Mode Set/Check Commands

Mode Set/Check CommandsMode Set/Check Commands

Set Features ModeSet Features Mode

Set Features Mode

Set Features ModeSet Features Mode

Enables or disables features supported by the drive. When the drive receives this command it:

1. Sets BSY,

2. Checks the contents of the Features register,

3. Clears BSY and

4. Generates an interrupt.

If the value of the register is not a feature supported by the drive, the command is aborted.
The acceptable values in the Features register are defined as follows:

VAL UE DESCRIPTION

02h E nabled Write Cache
03h Se t Transfer Mode based on va lue in Sector Count register
0 5h Ena ble Ad va nc ed Pow er Mana gement
4 2h E nable Automatic A c oustic Ma nage m ent. T he sect or count reg ist er contai ns the

A ut omat ic Acous tic Man ag e m ent level.

SECTOR LEVEL

81h-FDh Intermediate acoustic management levels

00h-7Fh reserved

44h Length of data appended on Read Long/Write Long commands specified in the

Identify Device information
55h Disable Read Look-ahead feature
6 6h D isab le re v erti ng to Power- on de f ault s
82h D isable Write Cache
8 5h D isab le A dvanc ed Pow er Mana gement

AAh Enable Read Look-ahead feature
BBh 4 bytes of Maxtor specific data appended on Read Long/Write Long commands
C2h Di sable Automatic Acoustic Manageme nt
CC h E nab le re ver t in g to Po we r- on def a ults

FFh Maxtor specific
FEh Max i mum performance

80h Minimum acoustic emanation level

7 – 6

INTERFACE COMMANDS

Read Native Max AddressRead Native Max Address

Read Native Max Address

Read Native Max AddressRead Native Max Address

This command returns the native maximum address. The native maximum address is the highest address
accepted by the drive in the factory default condition. The native maximum address is the maximum address
that is valid when using the SET MAX ADDRESS command.

Set MaxSet Max

Set Max

Set MaxSet Max

Individual SET MAX commands are identified by the value placed in the Features register. After successful
command completion, all read and write access attempts to addresses greater than specified by the successful
SET MAX ADDRESS command are rejected with an IDNF error. IDENTIFY DEVICE response words 1,
54, 57, 60 and 71 will reflect the maximum address set with this command.

VALUE C OMMAND

00h obsolete
01h Set Max Set Password
02h Set Max Lock
03h Set Max Unlock
04h Set Max Freeze Lock

05h-F Fh re served

Set Max PasswordSet Max Password

Set Max Password

Set Max PasswordSet Max Password

This sub-command requests a transfer of a single sector of data from the host. The password is retained by
the drive until the next power cycle.

Set Max LockSet Max Lock

Set Max Lock

Set Max LockSet Max Lock

After this sub-command is completed any other SET MAX commands except SET MAX UNLOCK and
SET MAX FREEZE LOCK are rejected. The drive remains in this state until a power cycle or the
acceptance of a SET MAX UNLOCK or SET MAX FREEZE LOCK command.

Set Max UnlockSet Max Unlock

Set Max Unlock

Set Max UnlockSet Max Unlock

This sub-command requests a transfer of a single sector of data from the host. The password supplied in the
sector of data transferred will be compared with the stored SET MAX password.

If the password compare fails, then the drive returns command aborted and decrements the unlock counter.
On the acceptance of the SET MAX LOCK command, this counter is set to a value of five and will be
decremented for each password mismatch when SET MAX UNLOCK is issued and the drive is locked.
When this counter reaches zero, then the SET MAX UNLOCK command will return command aborted
until a power cycle.

If the password compare matches, then the drive will make a transition to the Set_Max_Unlocked state and
all SET MAX commands will be accepted.

Set Max Freeze LockSet Max Freeze Lock

Set Max Freeze Lock

Set Max Freeze LockSet Max Freeze Lock

After sub-command completion any subsequent SET MAX commands are rejected. Commands disabled by
SET MAX FREEZE LOCK are:

Set Max Address
Set Max Set Password
Set Max Lock
Set Max Unlock

7 – 7

INTERFACE COMMANDS

Power Mode CommandsPower Mode Commands

Power Mode Commands

Power Mode CommandsPower Mode Commands

Standby Immediate – 94h/E0hStandby Immediate – 94h/E0h

Standby Immediate – 94h/E0h

Standby Immediate – 94h/E0hStandby Immediate – 94h/E0h

Spin down and do not change time out value. This command will spin the drive down and cause the drive
to enter the STANDBY MODE immediately. If the drive is already spun down, the spin down sequence is
not executed.

Idle Immediate – 95h/E1hIdle Immediate – 95h/E1h

Idle Immediate – 95h/E1h

Idle Immediate – 95h/E1hIdle Immediate – 95h/E1h

Spin up and do not change time out value. This command will spin up the spin motor if the drive is spun
down, and cause the drive to enter the IDLE MODE immediately. If the drive is already spinning, the spin
up sequence is not executed. The actuator is parked and some circuits are powered off.

Standby – 96h/E2hStandby – 96h/E2h

Standby – 96h/E2h

Standby – 96h/E2hStandby – 96h/E2h

Spin down and change time out value. This command will spin the drive down and cause the drive to enter
the STANDBY MODE immediately. If the drive is already spun down, the spin down sequence is not
executed. A non-zero value placed in the sector count register will enable the Automatic Power Down
sequence. The timer will begin counting down when the drive returns to the IDLE MODE. A value of zero
placed in the sector count register will disable the Automatic Power Down sequence.

Idle – 97h/E3hIdle – 97h/E3h

Idle – 97h/E3h

Idle – 97h/E3hIdle – 97h/E3h

Spin up and change time out value. This command will spin-up the spin motor if the drive is spun-down.
If the drive is already spinning, the spin up sequence is not executed. A non-zero value placed in the Sector
Count register will enable the Automatic Power Down sequence and their timer will begin counting down
immediately. A value of zero placed in the Sector Count register will disable the Automatic Power Down
sequence. The actuator is parked and some circuits are powered off.

TIMER VALUE TIME-OUT PERIOD

0 Time-out disabled

1 - 240 (value * 5) seconds

24 1 - 251 ((v alue - 240 ) * 30) mi nute s

252 21 minutes
253 Vendor unique period = 10 hours
254 Reserved
255 21 minutes, 15 seconds

Check Power Mode – 98h/E5hCheck Power Mode – 98h/E5h

Check Power Mode – 98h/E5h

Check Power Mode – 98h/E5hCheck Power Mode – 98h/E5h

This command returns a code in the Sector Count register that determines the current Power Mode status of
the drive. If the drive is in, going to, or recovering from the STANDBY MODE the drive sets the Sector
Count register to OOh. If the drive is in the IDLE MODE or ACTIVE MODE, the drive sets the Sector
Count register to FFh.

Set Sleep Mode – 99h/E6hSet Sleep Mode – 99h/E6h

Set Sleep Mode – 99h/E6h

Set Sleep Mode – 99h/E6hSet Sleep Mode – 99h/E6h

This command will spin the drive down and cause the drive to enter the SLEEP MODE immediately. If the
drive is already spun down, the spin down sequence is not executed.

Note: The only way to recover from SLEEP MODE is with a software reset or a hardware reset.

7 – 8

INTERFACE COMMANDS

Default Power-on ConditionDefault Power-on Condition

Default Power-on Condition

Default Power-on ConditionDefault Power-on Condition

The drive’s default power on condition is the ACTIVE MODE.

Upon receiving a Power Mode command, except the SLEEP MODE command, the drive sets BSY and
performs the requested power operation. Once the requested Power Mode change has begun, the drive
resets BSY and generates an interrupt - without waiting for the drive to spin up or spin down. Upon
receiving a SLEEP MODE command the drive is spun down, and when it is stopped, the drive resets BSY
and generates an interrupt.

When enabling the Automatic Power Down sequence, the value placed in the Sector Count register is
multiplied by five seconds to obtain the Time-out Interval value. If no drive commands are received from
the host within the Time-out Interval, the drive automatically enters the STANDBY mode. The minimum
value is 5 seconds.

While the drive is in STANDBY MODE, any commands received from the host are accepted and executed
as they would in normal operation, except that the spin motor is started if required to execute a disk
command. Under these conditions, the drive will set BSY when command processing would normally begin
and will leave BSY set until the drive comes up to speed and the disk command can be executed. Disk
commands issued while the drive is in STANDBY MODE, restarts the Time-out Interval after completing
the command. A reset must be issued before attempting to issue any commands while the drive in
SLEEP MODE.

7 – 9

INTERFACE COMMANDS

Initialization CommandsInitialization Commands

Initialization Commands

Initialization CommandsInitialization Commands

Identify DriveIdentify Drive

Identify Drive

Identify DriveIdentify Drive

Allows the host to receive parameter information from the drive.
When the command is received, the drive:

1. Sets BSY,

2. Stores the required parameter information in the sector buffer,

3. Sets the DRQ bit and

4. Generates an interrupt.

The host may then read the information out of the sector buffer. Parameter words in the buffer follow.
Note that all reserved bits or words should be zeroes.

WOR D CO NTENT DE S CRIPTION

0 General conf i gur ation

1 Numbe r of logical cylinders
2Reserved
3 Number of logical heads

4-5 Retired

6 Number of logical sectors per logical track

7-8 Reserved

9 Retired

10 - 19 Drive serial number (20 ASCII characters)

20 - 21 Retired

22 Obsolete
2 3 - 26 F irmw are revision (8 AS C I I char a c t ers)
27 - 46 Model number (40 ASCII characters )

47 Maxim um num ber of s ect ors that c an be t ransfe rre d p er i nt errup t on re ad a nd write multiple c omm ands

48 Reserved

49 Capabili ties

15 = device (0 = ATA device, 1 = ATAPI)
14 -8 = retir ed

7, 1 = removable media device
6, 1 = not removable controller and/or devi ce
5-3 = retired
2 = resp onse i ncomplete

1 = retired

0 = reserved

15 - 14 = res erved
13 = s tandby time r (1 = values as specified in this s tandard are supported, 0 = values are Maxtor specific )
12 = reserved (advanc ed PIO mode support)
11 , 1 = IORD Y s upp orted, 0 = IO R D Y m ay be s u pp orted
10, 1 = IORDY can be di sabled

9-8 = shall be set to one. Used by Identify Packet Device comm and.
7 -0 = not us ed

7 – 10

-W ORD CONT ENT DESCRIPTION

50 Reserved

51 - 52 Obsolete

53 15 -3 = rese rved

2, 1 = the fields supported in words 88 are valid, 0 = the fie lds supported in words 88 are not valid
1, 1 = the fields reports in words 64-70 are valid, 0 = the fields reports in words 64-70 are not valid

0, 1 = the fields reports in words 54-58 are valid, 0 = the fields reports in words 54-58 are not valid
54 Number of current logical cylinders
55 N um ber of curr en t logi ca l hea d s
56 Numbe r of logica l secto rs pe r tra ck

5 7 - 58 C urr e nt ca pac i ty in se ct or s

59 15- 9 = re se rved

8, 1 = multiple se ctor setting is valid

7-0 xxh = current setting for number of sectors that canbe transferred per interrupt on Read/Write Multiple

command

60 - 61 Total number of user addressable sectors (LBA mode only)

62 obsolete
63 15 -11 = res erved

1 0, 1 = M ult i-w ord D M A mode 2 i s selected, 0 = Multi -w ord D MA m ode 2 is no t se l ect ed

9, 1 = M ulti- w ord DMA mo de 1 is selected, 0 = M ulti-word DMA mode 1 is not selected

8, 1 = M ult i -wo rd D M A m ode 0 is s elected, 0 = Mu lt i-word D M A m ode 0 is no t s ele c ted

7- 3, = re se rved

2, 1 = Multi-word DMA mode 2 and below are supported

1, 1 = Multi-word DMA mode 1 and below are supported

0, 1 = Multi-word DMA mode 0 is supported

7-0 = Multi=word DMA transfer modes supported
64 15 -8 = re s erved, 7-0 = advanced PIO tr ansf er modes s upp orted
65 Minimum multi-word DMA transfer cycle time per word (15-0 = cycle time in nanoseconds)
66 Ma nufacturer's reco mme d ed mu lti-word DMA tr a nsfer cycle ti me (15 -0 = cycle ti me i n nanose co nds)
67 Mi ni mum P IO transfer cycle ti me without flow control (15 -0 = cycle ti me in nano seco nds )
68 M ini m um PIO t ransf er c yc le time wi t h IO R D Y f l ow control ( 15-0 = c y c le time i n nano s econds)

69-74 reserved

75 Q ue ue dep t h, 15 -3 = re se rve d, 4- 0, max im um que ue d ept h - 1

76-79 reserved

80 M ajor v ersion num be r

15, re served , 1 4-6 = rese rved for ATA/ATAPI-1 4 to ATA /ATAPI-6 r e spectively

5, 1 = supp orts ATA/ATAPI-5

4, 1 = supp orts ATA/ATAPI-4
3, 1 = supports ATA-3
2, 1 = supports ATA-2
1, obsolete
0, re se rved

81 Minor v ersion num be r
82 Command set supported. If words 82 and 83 = 0000h or FFFFh c ommand set notification not supported.

15, obsolet e
14, 1 = supports the NOP command
13, 1 = supports the Read Buffer command
12, 1 = sup p o rts the Wr ite Buffer command
11, ob solete
10, 1 = supports Host-Protected Area feature set
9, 1 = supports the Device Reset command
8, 1 = supports Service Interupt
7, 1 = supports Release Interupt
6, 1 = supports Look Ahead
5, 1 = s uppo r t s Write C ache

4, shall be cleared to zero
3, 1 = s upports the Power Management feature command
2, 1 = s uppo rt s the Re mo vab le Me di a fea ture com ma nd
1, 1 = s upports the SecurityMode feature command
0, 1 = supports the SMART feature set

INTERFACE COMMANDS

7 – 11

INTERFACE COMMANDS

WOR D CO NTENT DE S CRIPTION

83 Command s ets s uppo rt ed . If w ord s 82 and 83 = 00 0 0h o r FFF F h c omma nd set notifi c atio n not s upp orted.

15-10, as currently defined

9 , 1 = Automatic A c oust ic M anage ment f eature set s u pported
8-0, as currently defined

84 Command s et exte ns io ns sup po rted. If words 8 4, 85 a nd 8 6 = 000 0h or FF F F h command s et notificati on not

supported.
15 = shall be cleared to zero
14 = shall be set to one
13 -0 = re s erved

85 Command set enabled. If words 84, 85 and 86 = 0000h or F FFFh command set notification not suppor ted.

15 , ob s olete
14, 1 = NOP command enabled
13, 1 = Read Buffer command enabled
12, 1 = Write Buffer command enabled
11 , ob s olete
10, 1 = Host Protected Area feature set enabled

9, 1 = De vi ce Rese t co mmand e nabled

8, 1 = Service Interrupt enabled

7, 1 = Release Interrupt enabled

6, 1 = Look Ahead enabled

5, 1 = Write Cache enabled

4, 1 = Packet command feature set enabled

3, 1 = Power Mangement feature set enabled

2, 1 = Removable Media feature set enabled
1, 1 = Security Mode feature set enabled

0, 1 = SMART feature set enabled

86 Command s ets s uppo rt ed . If w ord s 82 and 83 = 00 0 0h o r FFF F h c omma nd set notifi c atio n not s upp orted.

15-10, as currently defined

9 , 1 = Automatic A c oust ic M anage ment f eature set s u pported

8-0, as currently defined

88 Ult r a D M A

15-14 reserved
13 1 = Ultra DMA mode 5 is selected

0 = Ultr a D MA mo de 5 is no t se le cted
12 1 = Ultra DMA mode 4 is selected

0 = Ultr a D MA mo de 4 is no t se le cted
11 1 = U lt ra DMA mo de 3 is sele cted

0 = Ultr a D MA mo de 3 is no t se le cted
10 1 = Ultra DMA mode 2 is selected

0 = Ultr a D MA mo de 2 is no t se le cted

9 1 = Ultra D M A mode 1 i s s ele c ted

0 = Ultr a D MA mo de 1 is no t se le cted

8 1 = Ultra D M A mode 0 i s s ele c ted

0 = Ultr a D MA mo de 0 is no t se le cted

7-6 reserved

5 1 = Ultra DMA mode 5 and below are supported

4 1 = Ultra DMA mode 4 and below are supported

3 1 = Ultra DMA mode 3 and below are supported

2 1 = Ultra DMA mode 2 and below are supported
1 1 = Ultra DMA mode 1 and below are supported

127 reserved
128 S ecurity Status

129-130 reserved

131 Spin at power-up, but 0 is asserted when no spin at power-up is enabled.
132-159 Maxtor-specific (not used)
160-255 reserved

0 1 = Ult ra D MA mod e 0 is sup por t ed

15-9 re serv ed

8 Security L evel 0 = High, 1 = Maximum
7-5 reserved
4 1 = S e curity count expired
3 1 = Security froze n
2 1 = Security locked

1 1 = Se curity e nabled

0 1 = Se curity supported

7 – 12

INTERFACE COMMANDS

Initialize Drive ParametersInitialize Drive Parameters

Initialize Drive Parameters

Initialize Drive ParametersInitialize Drive Parameters

Enables the drive to operate as any logical drive type. The drive will always be in the translate mode because
of Zone Density Recording, which varies the number of sectors per track depending on the zone.
Through setting the Sector Count Register and Drive Head Register, this command lets the host alter the
drive's logical configuration. As a result, the drive can operate as any equal to or less than capacity drive type.
Do not exceed the total number of sectors available on the drive:

When this command is executed, the drive reads the Sector Counter Register and the Drive Head Register
(and so determines the number of the logical sectors per track and maximum logical head number per
cylinder and will calculate the number of logical cylinders.)

Upon receipt of the command, the drive:

1. Sets BSY,

2. Saves the parameters,

3. Resets BSY and

4. Generates an interrupt.

To specify maximum heads, write 1 less than the maximum (e.g. write 4 for a 5 head drive). To specify
maximum sectors, specify the actual number of sectors (e.g. 17 for a maximum of 17 sectors/track).

The sector count and head values are not checked for validity by this command. If they are invalid, no error
will be posted until an illegal access is made by some other command.

Moves the read/write heads from anywhere on the disk to cylinder 0.
When this command is received, the drive:

1. Sets BSY and

2. Issues a seek to cylinder zero.

The drive waits for the seek to complete, then the drive:

1. Updates status,

2. Resets BSY and

3. Generates an interrupt.

If the drive cannot reach cylinder 0, the Error bit is set in the Status register, and the Track 0 bit is set in the
Error register.

NOTE: If a maximum head and sector number is selected – such that the number of cylinders will exceed 65,535 – then
the maximum cylinder value will be reduced to 65, 535.

7 – 13

INTERFACE COMMANDS

Seek, Format and Diagnostic CommandsSeek, Format and Diagnostic Commands

Seek, Format and Diagnostic Commands

Seek, Format and Diagnostic CommandsSeek, Format and Diagnostic Commands

SeekSeek

Seek

SeekSeek

Initiates a seek to the track, and selects the head specified in the Command block.

1. Sets BSY in the Status register,

2. Initiates the Seek,

3. Resets BSY and

4. Generates an interrupt.

The drive does not wait for the seek to complete before returning the interrupt. If a new command is issued
to a drive during the execution of a Seek command, the drive will wait (with BSY active) for the Seek to
complete before executing the new command.

Format TrackFormat Track

Format Track

Format TrackFormat Track

Formats the track specified in the Command Block. Shortly after the Command register is written, the drive
sets the bit, and waits for the host to fill the sector buffer with the interleave table. When the buffer is full,
the drive resets DRQ, sets BSY and begins command execution. If the drive is not already on the desired
track, an implied seek is performed. Once at the desired track the data fields are written with all zeroes.

Execute Drive DiagnosticExecute Drive Diagnostic

Execute Drive Diagnostic

Execute Drive DiagnosticExecute Drive Diagnostic

Commands the drive to implement the internal diagnostic tests. (These tests are executed only upon
command receipt; they do not run automatically at power up or after a reset.)

The drive sets BSY immediately upon receiving this command. The following table presents the codes and
their descriptions. Note that the value in the Error register should be viewed as a unique 8 bit Code.

ERROR CO DE DE SC RIPTION

01 No er ro r de te ct ed

00 Master drive failed

80, 82 Master and slave drives failed

81 Slave drive failed

Note: If a slave drive fails diagnostics, the master drive OR’s 80h with its own status, and loads that code
into the Error register. If a slave drive passes diagnostics (or a slave is absent), the master drive OR’s 00
with its own status and loads that code into the Error register.

7 – 14

INTERFACE COMMANDS

S.M.A.R.T. Command SetS.M.A.R.T. Command Set

S.M.A.R.T. Command Set

S.M.A.R.T. Command SetS.M.A.R.T. Command Set

Execute S.M.A.R.T.Execute S.M.A.R.T.

Execute S.M.A.R.T.

Execute S.M.A.R.T.Execute S.M.A.R.T.

The Self-Monitoring Analysis and Reporting Technology (S.M.A.R.T.) command has been implemented to
improve the data integrity and data availability of hard disk drives. In some cases, a S.M.A.R.T. capable device
will predict an impending failure with sufficient time to allow users to backup their data and replace the
drive before data loss or loss of service. In addition to S.M.A.R.T., DiamondMax drives support DST and all
of its options.

The S.M.A.R.T. sub-commands (listed below) comprise the ATA S.M.A.R.T. feature set that provide access
to S.M.A.R.T. attribute values, attribute thresholds and other logging and reporting information. Prior to
writing a S.M.A.R.T. command to the device’s command register, key values must be written by the host
into the device’s Cylinder Low and Cylinder High registers, or the command will be aborted. For any
S.M.A.R.T. sub-command, if a device register is not specified as being written with a value by the host, then
the value in that register is undefined and will be ignored by the device.
The key values are:

Key Register

4Fh Cylinder Low (1F4h)
C2h Cylinder High (1F5h)

The S.M.A.R.T. sub-commands use a single command code (B0h) and are differentiated from one another
by the value placed in the Features register. In order to issue a command, the host must write the sub­command-specific code to the device’s Features register before writing the command code to the command
register. The sub-commands and their respective codes are:

D0h S.M.A.R.T. Read Attribute Value

This feature returns 512 bytes of attribute information to the host.

D1h S.M.A.R.T. Read Attribute Thresholds

This feature returns 512 bytes of warranty failure thresholds to the host.

D2h Enable/Disable Autosave

To enable this feature, set the sector count register to F1h (enable) or 0 (disable). Attribute values
are automatically saved to non-volatile storage on the device after five minutes of idle time and
before entering idle, sleep or standby modes. This feature is defaulted to “enabled” when
S.M.A.R.T. is enabled via the S.M.A.R.T. Enable Operations commands. The autosave feature
will not impact host system performance and does not need to be disabled.

D3h S.M.A.R.T. Save Attribute Value

This feature saves the current attribute values to non-volatile storage.

D4h Perform Off-Line Data Collection/DST

Data is collected from random seeks, timed pattern seek times and head margin tests. Supports
captive long and short; and non-captive long and short.

D5h S.M.A.R.T. Read Log Sector

Allows the host to read S.M.A.R.T. error log and host vendor-specific sectors.

D6h S.M.A.R.T. Write Log Sector

Allows the host to write S.M.A.R.T. error log and host vendor-specific sectors.

D8h Enable S.M.A.R.T.

D9h Disable S.M.A.R.T.

DAh S.M.A.R.T. Return Status

This feature allows the host to assess the status of a S.M.A.R.T. capable device by comparing all
saved attribute values with their corresponding warranty failure thresholds. If no thresholds are
exceeded, the drive is declared to have a positive health status. If any warranty failure threshold is
exceeded, the drive is declared to have a negative health status. Executing this sub-command
results in all attribute values being saved to non-volatile storage on the device.

DBh Enable/Disable Automatic Off-Line

To enable this feature, set the Sector Count register to F1h or 0 to disable.

7 – 15

SERVICE AND SUPPORT

SECTION 8

Service and SupportService and Support

Service and Support

Service and SupportService and Support

Service PolicyService Policy

Service Policy

Service PolicyService Policy

If a customer discovers a defect in a Maxtor hard drive, Maxtor will, at its option, repair or replace the disk
drive at no charge to the customer, provided it is returned during the warranty period. Drives must be properly
packaged in Maxtor packaging or Maxtor-approved packaging to obtain warranty service. Any unauthorized
repairs or adjustments to the drive void the warranty.

To consistently provide our customers with the best possible products and services, Maxtor developed the
Total Customer Satisfaction (TCS) program. Through the ongoing TCS process, Maxtor employees take
direct responsibility for every customer’s level of satisfaction – with Maxtor technology, price, quality,
delivery, service and support.

®®

®

No QuibbleNo Quibble

No Quibble

No QuibbleNo Quibble

Another TCS feature is Maxtor’s No Quibble Service® policy. By minimizing paperwork and processing,
No Quibble Service dramatically cuts the turnaround time normally required for repairs and returns.

Here’s how it works:

Service Service

Service

Service Service

®®

1. Customer visits www.maxtor.com or calls 1-800-2MAXTOR for a Return Material Authorization
(RMA) number and provides a credit card number,

2. Maxtor ships a replacement drive within 2 business days, and

3. Customer returns the original drive and credit card draft is destroyed.

Product SupportProduct Support

Product Support

Product SupportProduct Support

Technical Assistance/Customer ServiceTechnical Assistance/Customer Service

Technical Assistance/Customer Service

Technical Assistance/Customer ServiceTechnical Assistance/Customer Service

Hours of operation: 6 a.m. to 6 p.m. (Mountain Time) Monday through Friday.

North, Central and South America Languages supported: English, Spanish

Voice 800-2MAXTOR (800-262-9867)
E-mail www.maxtor.com

Outside Continental USA 303-678-2015

Europe, Middle East, Africa Languages supported: English, French, German
Hours of operation: 8:30 a.m. to 5 p.m. (Greenwich Mean Time) Monday through Thursday, 8:30 a.m.
to 4 p.m. Friday.

Voice + 353 1 204 1111
E-mail www.maxtor.com
Fax +353 1 286 1419
MaxFax + 353 1 204 1122

8 – 1

SERVICE AND SUPPORT

Asia/Pacific (APAC)

Australia Languages supported: English

Singapore Languages supported: English

Vox + 61 2 9369 3662
Fax + 61 2 9369 2082
MaxFax + 61 2 9369 4733
BBS + 61 2 9369 4293

Contact local Maxtor sales office

From D ial

Australia 1-800-124-328
Hong Kong 800-96-3387
Indonesia 803-65-6500
Japan 0031-65-3616
South Korea 0078-65-800-6500
Malaysia 1-800-80-1126
New Zealand 0800-44-6542
Singapore Toll Free 1-800-481-6788
Singapore Vox 65-8520220
Singapore Fax 65-251744
Taiwan 0080-65-1062
Thailand 001-800-65-6500

MaxInfo ServiceMaxInfo Service

MaxInfo Service

MaxInfo ServiceMaxInfo Service

Use a touch-tone phone to listen to technical information about Maxtor products and the top Q&A’s
from our 24-hour automated voice system.

Continental USA 800-2MAXTOR (800-262-9867)

Press 1, wait for announcement, listen for option

Outside Continental USA 303-678-2015, listen for option

®®

®

®®

MaxFaxMaxFax

MaxFax

MaxFaxMaxFax

Service Service

Service

Service Service

Use a touch-tone phone to order technical reference sheets, drive specifications, installation guides
and other documents from our 24-hour automated fax retrieval system. Requested items are sent directly
to your fax machine.

Continental USA Languages supported: English

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8 – 2

GlossaryGlossary

Glossary

GlossaryGlossary

GLOSSARY

GLOSSARY

AA

A

AA

access

To obtain data from, or place data into, RAM, a register,
or data storage device.

access time

The interval between the issuing of an access command
and the instant that the target data may be read or
written. Access time includes seek time, latency and
controller overhead time.

address

A number, generally binary, distinguishing a specific
member of an ordered set of locations. In disk
engineering, the address may consist of drives (unit
address), radial positions (cylinder address), or
circumferential position (sector address).

allocation

A process of assigning designated areas of the disk to
particular files.

alternate track

A spare track used in the event that a normal track
becomes damaged or is unusable.

analog

A signal or system that does not use digital states to
convey information. A signal may have any number of
significant states (values), contrasted to digital signals
which can only have two states.

ANSI

American National Standards Institute.

application program

A sequence of programmed instructions that tell the
computer how to perform some end-user task, such as
accounting or word processing.

BB

B

BB

bad block

A block that cannot store data because of a media flaw.

bit

An abbreviation for binary digit, of which there are two (0
and 1). A bit is the basic data unit of most digital
computers. A bit is usually part of a data byte or word,
but bits may be used singly to control or read logic “on­off” functions. The fundamental unit information, often
used loosely to refer to a circuit or magnetization state at
a particular instant in time.

BIOS

Acronym for Basic Input/Output System. The firmware
area of a CPU that controls operations through the
system bus and to the attached cards and peripheral
devices.

BPI

Acronym for bits per inch. See bit density.

block

A group of bytes handled, stored, and accessed as a
logical data unit, such as an individual file record.

buffer

A temporary data storage area that compensates for a
difference in data transfer rates and/or data processing
rates between sender and receiver.

bus

A collection of functionally parallel conductors that forms
an interconnection between functional blocks in a digital
device. A length of parallel conductors that forms a major
interconnection route between the computer system
CPU (central processing unit) and its peripheral
subsystems. Depending on its design, a bus may carry
data, addresses, power, and more.

areal density

Bit density (bits per inch) multiplied by track density
(tracks per inch) or bits per square inch.

asymmetry

A distortion of the readback signal which is shown in
different intervals between the positive and negative
voltage peaks.

auxiliary memory

Memory other than main memory; generally a mass­storage subsystem containing disk drives and backup
tape drives, controller(s) and buffer memory (also called
peripheral memory).

average access time

The average time to make all possible length accesses
(seeks).

average seek time

The average time to make all possible length seeks. A
typical measure of performance.

byte

An ordered collection of bits treated as a unit. Most
often, a byte is understood to consist of eight bits. One
byte is necessary to define an alphanumeric character.

CC

C

CC

cache

Random access memory (RAM) used as a buffer
between the CPU and the disk drive.

capacity

The amount of data, usually expressed in bytes, which
can be stored in a given device or portion of same.

GL – 1

GLOSSARY

central processing unit (CPU)

The heart of the computer system that executes
programmed instructions. It includes the arithmetic logic
unit (ALU) for performing all math and logic operations, a
control section for interpreting and executing
instructions, internal memory for temporary storage of
program variables and other functions.

channel

A collection of electronic circuits used in the process of
writing and reading information to and from magnetic
media.

character

An ordered collection of bits representing one of a set of
predefined symbols. Often the term is used
interchangeably with byte, but this is inexact.

closed loop

A control technique that enables the positioning system
to correct off-track errors in real time. The actual head
position is monitored and compared to the ideal track
position to determine any position error that might be
occurring. This information is then used to produce a
correction signal (feedback) that goes to the positioner to
correct the error. (See also track following servo).

closed loop servo

A servo control technique that uses position feedback to
correct off-track errors. See Track Following Servo.

cluster

The smallest allocatable unit of disk storage allowed by
MS-DOS; each FAT entry represents one cluster.

controller

An electronic device for connecting one or more mass
storage peripherals (rigid disk drives, tape drives, and
optical disk drives) to the input/output circuits of a host
computer. Controllers vary in complexity, with more
sophisticated units able to buffer and schedule
commands, correct data errors, and bypass media
defects without host intervention.

controller

A miniature CPU dedicated to controlling a peripheral
device, such as a disk drive, tape drive, video display
terminal, or printer. The controller executes commands
from the central processing unit and reissues commands
to the peripheral device.

correctable error

An error that can be overcome by the use of Error
Detection and Correction.

cylinder

On several disk surfaces sharing a common rotational
axis, the aggregate of tracks at a given radial position. A
set of disk tracks that are simultaneously under the set of
read/write heads. This three-dimensional storage volume
can be accessed after a single seek.

cylinder zero

The outermost cylinder in a drive that can be used for
data storage.

DD

D

DD

data

An ordered collection of information. In a specific case, it
is the information processed by a computer.

data separator

An electronic circuit which decodes playback data and
produces separate clock and data bits. Sometimes
incorrectly used to denote data synchronizer.

data synchronizer

An electronic circuit producing a clock signal that is
synchronous with the incoming data stream. This clock
signal is then used to decode the recording code being
used into user data.

data transfer rate

In a disk or tape drive, the rate at which data is
transferred to or from the storage media. It is usually
given in thousands of bits per second (Kbit/second) or
millions of bits per second (Mbit/second).

dedicated landing zone

A designated radial zone on the disk where contact
starting and stopping occur by design.

dedicated servo

A servo scheme in which a prerecorded pattern on an
otherwise unused disk surface provides position
information to the servo circuitry by means of a head
reading that surface.

defect

A magnetic imperfection in a recording surface.

defect management

A general methodology of avoiding data errors on a
recording surface by avoiding the use of known bad
areas of media. Usually defective sectors or tracks are
retired and data are written in alternate locations. Several
algorithms are possible such as “sector slipping,” or
“spare sector per track.”

defect map

A list of defects that fall within a pass/fail criteria of a user.
This list is usually used by an operating system or a disk
drive controller for defect management.

defect skipping

A defect management scheme for avoiding surface
defects. It has data written before and after the defect,
instead of using alternate tracks or sectors to avoid use
of the defective area.

density

Generally, recording density. See areal, bit, and storage
density.

DC erase

The method of erasing a track using a DC write/erase
current through either a Read/Write or Erase head.

digital

Any system that processes digital binary signals (having
only values of a 1 or 0; usually in bits and bytes) rather
than analog signals (signals that can have many values)

GL – 2

GLOSSARY

digital magnetic recording

See magnetic recording.

direct access

Access directly to memory location. (See random
access).

direct memory access (DMA)

A mean of data transfer between the device and host
memory without processor intervention.

directory

A listing of files maintained by the disk operation system
(DOS) or a data base management system to enable a
user to quickly access data files.

disk

A flat, circular piece of metal (usually aluminum) or plastic
(usually mylar) with a magnetic coating upon which
information can be recorded. (See, for example, floppy
disk or Winchester disk)

disk drive or disk memory device

The total electromechanical storage device containing
disks and read/write heads, head positioning mechanism,
drive motor, and electronics.

disk pack

A number of metal disks packaged in a canister for
removal from the disk drive (predecessor of Winchester
technology).

disk operating system (DOS)

The master computer system program that schedules
tasks, allocates the computer system resources, controls
accesses to mass storage devices, manages files, and so
forth. Typical disk operating systems include CP/M, MS­DOS, and UNIX.

disk storage

Auxiliary memory system containing disk drives.

disk transfer rate

The rate that digital data is transferred from one point to
another. Expressed in either bits/second or bytes/
second.

double frequency encoding

Another name for FM encoding. This is because all
possible data combinations will result in only two
possible temporal displacements of adjacent data bits,
specifically “1F” and 2F.”

EE

E

EE

early window

A data window that has been intentionally shifted in time
in an early direction.

embedded servo

A servo technique used for track following. Position
information is prerecorded between data areas in a track
so that a data head, and proper additional circuitry, can
determine the data head location with respect to the
center position of the track (or cylinder) in question.

erase

A process by which a signal recorded on a medium is
removed and the medium made ready for rerecording.

error correction code (ECC)

A mathematical algorithm that can detect and correct
errors in a data field. This is accomplished with the aid of
Check Bits added to the raw data.

error free

A recording surface that has no defects.

error rate

The number of errors (type must be specified) that occur
in a specified number of bits read.

error recovery procedure

The process that occurs in response to a data error. In a
drive without ECC, this would include re-calibration and
re-seeking to the specified track and rereading the
specified data.

extra pulse

Term used in surface certification. It is when a flux field
discontinuity remains after the recording surface is
erased, thereby producing an electrical output of a read
head passing over the area with the discontinuity. An
extra pulse occurs when the electrical output is larger
than a specified threshold.

FF

F

FF

feedback

In a closed-loop system, the output signal (from the
servo head) is used to modify the input signal (to the
positioner).

fetch

A read operation and its related data transfer operations.

file allocation table (FAT)

Allocates space on the disk for files, one cluster at a
time; locks out unusable clusters; identifies unused (free)
area; and lists a file’s location. With two FAT’s present,
the second copy ensures consistency and protects
against loss of data if one of the sectors on the first FAT
is damaged.

flux changes per inch

Synonymous with frpi (flux reversals per inch). Only in
MFM recording does 1 fci equal 1 bpi (bit per inch). In
run-length-limited encoding schemes, generally 1 fci
equals 1.5 bpi.

format

In a disk drive, the arrangement of data on a storage
media. A standard 5.25-inch disk format consists of 17,
26, or 36 sectors per track, and 512 bytes of data per
sector, plus identification, error correction, and other
bytes necessary for accessing and synchronizing data.

formatted capacity

The actual capacity available to store data in a mass
storage device. The formatted capacity is the gross
capacity, less the capacity taken up by the overhead data
used in formatting the sectors.

frequency modulation

A recording code. A flux reversal at the beginning of a
cell time represents clock bit; a “1” bit is a flux reversal at
the center of the cell time, and a “0” bit is an absence of
a flux reversal.

GL – 3

GLOSSARY

frequency response

A measure of how effectively a circuit or device transmits
the different frequencies applied to it. In disk and tape
drives this refers to the read/write channel. In disk drives,
it can also refer to the dynamic mechanical characteristics
of a positioning system.

GG

G

GG

gigabyte (GB)

One billion bytes (one thousand megabytes) or 10E9.

HH

H

HH

hard error

An error that is not able to be overcome by repeated
readings and repositioning means.

hard sectored

A technique where a digital signal indicates the
beginning of a sector on a track. This is contrasted to soft
sectoring, where the controller determines the beginning
of a sector by the reading of format information from the
disk.

head

The electromagnetic device that write (records), reads
(plays back), and erases data on a magnetic media. It
contains a read core(s) and/or a write core(s) and/or erase
core(s) which is/are used to produce or receive magnetic
flux. Sometimes the term is all inclusive to mean the
carriage assembly which includes the slider and flexure.

initialization

Applying input patterns or instructions to a device so that
all operational parameters are at a known value.

input

Data entering the computer to be processed; also user
commands.

input/output (I/O)

The process of entering data into or removing data from
a computer system or a peripheral device.

intelligent peripheral

A peripheral device that contains a processor or
microprocessor to enable it to interpret and execute
commands.

interface

The data transmitters, data receivers, logic, and wiring
that link one piece of computer equipment to another,
such as a disk drive to a controller or a controller to a
system bus.

interface standard

The interface specifications agreed to by various
manufacturers to promote industry-wide
interchangeability of products such as a disk drive.
Interface standards generally reduce product costs,
allows buyers to purchase from more than one source,
and allow faster market acceptance of new products.

interleave

An ordering of physical sectors to be skipped between
logical sectors on your hard disk.

head crash

The inadvertent touching of a disk by a head flying over
the disk (may destroy a portion of the media and/or the
head).

head disk assembly (HDA)

The mechanical portion of a rigid, fixed disk drive. It
usually includes disks, heads, spindle motor, and
actuator.

head loading zone

The non-data area on the disk set aside for the controlled
takeoff and landing of the Winchester heads when the
drive is turned on and off. Dedicated annulus on each
disk surface in which heads are loaded, unloaded, or
flying height is established. Head-disk contact may occur
in some instances; no data is recorded in this area.

head positioner

Also known as actuator, a mechanism that moves the
arms that carry read/write heads to the cylinder being
accessed.

II

I

II

index

Similar to a directory, but used to establish a physical to
logical cross reference. Used to update the physical disk
address (tracks and sectors) of files and to expedite
accesses.

inside diameter

The smallest radial position used for the recording and
playback of flux reversals on a magnetic disk surface.

I/O processor

Intelligent processor or controller that handles the input/
output operations of a computer.

interrupt

A signal, usually from a subsystem to a central
processing unit, to signify that an operation has been
completed or cannot be completed.

JJ

J

JJ

jumper

A small piece of plastic that slides over pairs of pins that
protrude from the circuit board on the hard drive to make
an electrical connection and activate a specific option.

KK

K

KK

kilobyte (KB)

A unit of measure of approximately 1,000 bytes.
(However, because computer memory is partitioned into
sizes that are a power of two, a kilobyte is really 1,024
bytes.)

LL

L

LL

landing zone or Lzone

The cylinder number/location to where the read/write
head(s) move upon power down.

late bit

A bit that is in the late half of the data window.

GL – 4

GLOSSARY

late window

A data window that has been shifted in a late direction to
facilitate data recovery.

latency

A delay encountered in a computer when waiting for a
specific response. In a disk drive there is both seek
latency and rotational latency. The time required for the
addressed sector to arrive under the head after the head
is positioned over the correct track. It is a result of the
disk’s rotational speed and must be considered in
determining the disk drive’s total access time.

logic

Electronic circuitry that switches on and off (“1” and “0”)
to perform functions.

logical address

A storage location address that may not relate directly to
a physical location. Usually used to request information
from a controller, which performs a logical to physical
address conversion, and in turn, retrieves the data from a
physical location in the mass storage peripheral.

logical block addressing

Defines the addressing of the device by the linear
mapping of sectors.

logical sector

The lowest unit of space that DOS can access through a
device driver; one or more physical sectors.

low frequency

The lowest recording frequency used in a particular
magnetic recording device. With FM or MFM channel
codes, this frequency is also called “IF.”

MM

M

MM

main memory

Random-access memory (RAM) used by the central
processing unit (CPU) for storing program instructions
and data currently being processed by those instructions.
(See also random access memory.)

mass storage

Auxiliary memory used in conjunctions with main
memory; generally having a large, on-line storage
capacity.

megabyte (MB)

A unit of measure approximately one million bytes
(actually 1,048,576 bytes) or 10E6.

missing pulse

A term used in surface certification. It is when a
prerecorded signal is reduced in amplitude by a certain
specified percentage.

modified frequency modulation (MFM)

A method of encoding digital data signals for recording
on magnetic media. Also called “three frequency
recording.” Recording code that only uses synchronizing
clock pulse if data bits are not present. Doubles the lineal
bit density without increasing the lineal flux reversal
density, compared to Frequency Modulation.

modified modified frequency modulation (MMFM)

A recording code similar to MFM that has a longer run
length limited distance.

modulation

1. Readback voltage fluctuation usually related to the
rotational period of a disk. 2. A recording code, such as
FM, MFM, or RLL, to translate between flux reversals
and bits or bytes.

NN

N

NN

non-return to zero

A form of data encoding that is not self-clocking, in other
words, it needs to be provided with an external bit cell
clock signal. Generally used in higher-performance disk
drives.

OO

O

OO

off-line

processing or peripheral operations performed while
disconnected from the system CPU via the system bus.

on-line

processing or peripheral operations performed while
disconnected from the system CPU via the system bus.

open loop servo

A head positioning system that does not use positional
information to verify and correct the radial location of the
head relative to the track. This is usually achieved by use
of a stepper motor which has predetermined stopping
point that corresponds to track locations.

operating system

A software program that organizes the actions of the
parts of the computer and its peripheral devices. (See
disk operating system.)

memory

Any device or storage system capable of storing and
retrieving information. (See also storage definitions.)

microcomputer

A computer whose central processing unit is a
microprocessor. It is usually, but not necessarily, desktop
size.

microprocessor

A central processing unit (CPU) manufactured as a chip or
a small number of chips.

outside diameter

The largest radius recording track on a disk.

overwrite

A test that measures the residual 1F recorded frequency
on a track after being overwritten by a 2F signal.
Variations of the test exist.

GL – 5

GLOSSARY

PP

P

PP

parallelism

1. The condition of two planes or lines being parallel.
Important in disk drives because a lack of it in mechanical
assemblies can result in positioning inaccuracy. More
precisely: planes-coplanar; lines-colinear. 2. Is the local
variation in disk thickness measured independently of
thickness itself. 3. The ability of a multiprocessor
computer to allocate more than one processor (CPU) to a
computing problem, where each CPU works on a
separate problem or separate segment of that problem.
Also referred to as parallel processing.

parity

A simple method of data error detections that always
makes numbers either odd or even, using an extra bit in
which the total number of binary 1s (or 0s) in a byte is
always odd or always even; thus, in an odd parity
scheme, every byte has eight bits of data and one parity
bit. If using odd parity and the number of 1 bits
comprising the byte of data is not odd, the ninth or parity
bit is set to 1 to create the odd parity. In this way, a byte
of data can be checked for accurate transmission by
simply counting the bits for an odd parity indication. If the
count is ever even, an error is indicated.

partition

A logical section of a disk drive, each of which becomes
a logical device with a drive letter.

peak shift

The shifting in time of the zero-slope portion of a
readback voltage from the values contained in the write
current waveform. Sometimes incorrectly used to
describe bit jitter.

peripheral equipment

Auxiliary memory, displays, printers, and other equipment
usually attached to a computer system’s CPU by
controllers and cables. (They are often packaged
together in a desktop computer.)

processing

The process of the computer handling, manipulating and
modifying data such as arithmetic calculation, file lookup
and updating, and word pressing.

pulse crowding

Modification of playback amplitude due to super­positioning of adjacent flux reversal fields being sensed
by the read/write gap.

pulse detect

A digital pulse train in which each leading edge or each
edge corresponds to a magnetic transition read from the
disk. If transition qualification circuitry exists in the drive,
this signal is the output of same. Also known as
transition detect.

RR

R

RR

random access memory (RAM)

Memory designed so that any storage location can be
accessed randomly, directly and individually. This is
contrasted to sequential access devices such as tape
drives.

read

To access a storage location and obtain previously
recorded data. To sense the presence of flux reversals
on magnetic media. Usually implemented such that a
dynamic flux amplitude will cause a proportional electrical
output from the transducer.

read gate signal

A digital input signal which causes the drive circuitry to
recover data.

read only memory (ROM)

A form of memory which cannot be changed in formal
operational modes. Many different types are available.
RAM is used for permanent information storage.
Computer control programs are often stored in ROM
applications.

phase locked loop (PLL)

A circuit whose output locks onto and tracks the
frequency of an input signal. Sometimes incorrectly
called a data separator.

phase margin

Measure in degrees of the amount of difference
between excursions from the window center where flux
reversals can occur and the edge of the data window.
Similar to window margin.

physical sector

The smallest grouping of data on the hard disk; always
512 bytes.

PIO

Programmable Input Output. A means of accessing
device registers. Also describes one form of data
transfers. PIO data transfers are performed by the host
processor using PIO register accesses to the data
register.

plated thin film media

Magnetic disk memory media having its surface plated
with a thin coating of a metallic alloy instead of being
coated with oxide.

GL – 6

read/write head

The recording element which writes data to the magnetic
media and reads recorded data from the media.

re-calibrate

The action of moving the head of a disk drive to cylinder
zero.

recoverable error

A read error, transient or otherwise, falling within the
capability of an ECC mechanism to correct, or able to
overcome by rereading the data in question.

rotational latency

The amount of delay in obtaining information from a disk
drive attributable to the rotation of the disk.

run-length limited

An encoding process that repositions data bits and limits
the length of zero bits in order to compress information
being stored on disks.

run-length limited encoding

A recording code. Sometimes meant to denote “2.7
RLL” which can signify 1.5 times the bits as MFM, given
the same number of flux reversals in a given lineal
distance.

GLOSSARY

SS

S

SS

sector

A logical segment of information on a particular track. The
smallest addressable unit of storage on a disk. Tracks are
made of sectors.

sector pulse signal

A digital signal pulse present in hard sectored drives
which indicates the beginning of a sector. Embedded
servo pattern or other prerecorded information may be
present on the disk when sector is active.

seek

A random access operation by the disk drive. The act of
moving a set of read/write heads so that one of them is
over the desired cylinder. The actuator or positioner
moves the heads to the cylinder containing the desired
track and sector.

seek complete signal

A digital signal level which indicates that the positioner is
not moving and is located over a cylinder or offset
position.

seek time

The amount of time between when a step pulse or seek
command is issued until the head settles onto the
desired cylinder. Sometimes is measured without settling
times.

sequential access

The writing or reading of data in a sequential order such
as reading data blocks stored one after the other on
magnetic tape. This is contrasted to random access of
information.

servo burst

A momentary servo pattern used in embedded servo
control systems usually positioned between sectors or at
the end of a track.

servo control

A technique by which the speed or position of a moving
device is forced into conformity with a desired or
standard speed or position.

servo head

A magnetic head designed specifically for accurately
reading servo data.

servo pattern

A readback signal that indicates the position of a head
relative to a track.

servo surface

A recording surface in a multi-surface disk drive that only
contains control information which provides timing, head
position, and track-following information for the data
surfaces.

servo system

An automatic system for maintaining the read/write head
on track; can be either “open loop,” “quasi-closed
loop,” or “closed loop.”

servo track

A track on a servo surface. The prerecorded reference
track on the dedicated servo surface of a disk drive. All
data track positions are compared to their corresponding
servo track to determine “off track”/”on track” position.

settling time

The time it takes a head to stop vibrating, within
specified limits, after it reaches the desired cylinder.

silicon

Semiconductor material generally used to manufacture
microprocessors and other integrated circuit chips.

small computer system interface (SCSI)

An intelligent interface that incorporates controller
functions directly into the drive.

S.M.A.R.T. capability

Self-Monitoring Analysis and Reporting Technology.
Prediction of device degradation and/or faults.

soft error

A data error which can be overcome by rereading the
data or repositioning the head.

soft sectored

A technique where the controller determines the
beginning of a sector by the reading of format
information from the disk. This is contrasted to hard
sectoring where a digital signal indicates the beginning of
a sector on a track.

software

Applications programs, operating systems, and other
programs (as opposed to hardware).

spindle

The rotating hub structure to which the disks are
attached.

spindle motor

The motor that rotates the spindle and therefore the
disks.

sputtered media

Magnetic disk or tape that has the magnetic layer
deposited by sputtering means.

stepper motor

A motor that has known detent positions where the rotor
will stop with the proper control in some cases. The
digitally controlled motor moves the head positioner from
track to track in small, step-like motions.

storage capacity

The amount of data that can be stored in a memory
location, usually specified in kilobytes for main memory
and floppy drives and megabytes for mass storage
devices.

storage density

Usually refers to recording density (BPI, TPI, or a
combination of the two.)

storage location

A memory location, identified by an address where
information may be read or written.

GL – 7

GLOSSARY

strobe offset signal

A group of digital input signal levels which cause the
read PLL and/or data decoder to shift the decoding
windows by fractional amounts. Often early/late are
modified when two signals are used.

TT

T

TT

thin-film head

A magnetic transducer manufactured by deposition of
magnetic and electrical materials on a base material
contrasted with prior art mechanical methods. Read/write
heads whose read/write element is deposited using
integrated circuit techniques rather than being manually
wound.

thin-film media

See plated thin film media.

track

One surface of a cylinder. A path which contains
reproducible information left on a magnetic medium by
recording means energized from a single channel.

track-following servo

A closed-loop positioner control system that continuously
corrects the position of the disk drive’s heads by utilizing
a reference track and a feedback loop in the head
positioning system. (See also closed loop.)

tracks per inch (TPI)

A measurement of radial density. Tracks per inch of disk
radius.

track positioning

The method, both mechanical and electrical, used to
position the heads over the correct cylinder in a disk
drive system.

UU

U

UU

un-correctable error

An error that is not able to be overcome with Error
Detection and Correction.

unformatted capacity

Storage capacity of disk drive prior to formatting; also
called the gross capacity. (See format.) The raw capacity
of a drive not taking into account the capacity loss due to
storage of the format control information on the disk
surfaces.

WW

W

WW

Whitney head

A successor to the original Winchester read/write head
design. The primary change was to make the flexure
smaller and more rigid. First used in IBM 3370/3380.

Whitney technology

A method of constructing a read/write head in a rigid disk
drive using a Whitney head. In all other details it is the
same as Winchester technology.

Winchester head

The read/write head used in Winchester technology,
non-removable media disk drives. May be either a
monolithic or composite type. It is aerodynamically
designed to fly within microinches of the disk surface.

Winchester technology

A method of constructing a rigid disk drive using
concepts introduced in the IBM model 3340 disk drive.
The primary changes from prior technology was to lower
the mass of the slider, use of a monolithic slider, radically
changing the design of the flexure and having the slider
come to rest on a lubricated disk surface when disk
rotation ceases. In addition to the above, a totally sealed
chamber containing the read/write heads and disks was
used to protect against contamination.

window margin

The amount of tolerance a read/write system has for
transition jitter at a specified error rate level.

word

A number of bits, typically a multiple of eight, processed
in parallel (in a single operation). Standard word lengths
are 8, 16, 32 and 64 bits (1, 2, 4, or 8 bytes).

write

The recording of flux reversals on a magnetic media.

write pre-compensation

The intentional time shifting of write data to offset the
effects of bit shift in magnetic recording.

write gate signal

A digital input signal level which causes the drive circuitry
to record (write) data.

unrecoverable error

A read error falling outside the capability of an ECC
mechanism to correct, or not able to be overcome by
rereading the data in question, with or without
repositioning the head.

VV

V

VV

voice coil motor

A positioning motor that uses the same principle as a
voice coil in a loudspeaker. The motor has no detent
positions. The mechanical motion output of it can be
either rotary or linear.

GL – 8