Silicon Storage Technology Inc SST39VF080-90-4C-EK, SST39VF080-90-4C-EI, SST39VF080-90-4C-B3K, SST39VF080-90-4C-B3I, SST39VF080-70-4I-EK Datasheet

Data Sheet

©2001 Silicon Storage Technology, Inc.
S71146-03-000 6/01 396

1

The SST logo and SuperFlash are registered trademarks of Silicon Storage Technology, Inc.

MPF is a trademark of Silicon Storage Technology, Inc.

These specifications are subject to change without notice.

8 Mbit / 16 Mbit (x8) Multi-Purpose Flash

SST39LF080 / SST39LF016 / SST39VF080 / SST39VF016

FEATURES:

• Organized as 1M x8 / 2M x8

• Single Voltage Read and Write Operations

– 3.0-3.6V for SST39LF080/016
– 2.7-3.6V for SST39VF080/016

• Superior Reliability

– Endurance: 100,000 Cycles (typical)
– Greater than 100 years Data Retention

• Low Power Consumption:

– Ac ti ve Current: 15 mA (typical)
– Standby Current: 4 µA (typical)
– Auto Low Power Mode: 4 µA (typical)

• Sector-Erase Capability

– Uniform 4 KByte sectors

• Block-Erase Capability

– Uniform 64 KByte blocks

• Fast Read Access Time:

– 55 ns for SST39LF080/016
– 70 and 90 ns for SST39VF080/ 016

• Latched Address and Data

• Fast Erase and Byte-Program:

– Sector-Erase Time: 18 ms (typical)
– Block-Erase Time: 18 ms (typical)
– Chip-Erase Time: 70 ms (typical)
– Byte-Program Time: 14 µs (typical)
– Chip Rewrite Time:

15 seconds (typical) for SST39LF/VF080
30 seconds (typical) for SST39LF/VF016

• Automatic Write Timing

– Internal V

PP

Generation

• End-of-Write Detection

– Toggle Bit
– Data# Polling

• CMOS I/O Compatibility

• JEDEC Standard

– Flash EEPROM Pinouts and command sets

• Packages Available

– 40-lead TSOP (10mm x 20mm)
– 48-ball TFBGA (6mm x 8mm)

PRODUCT DESCRIPTION

The SST39LF/VF080 and SST39LF/VF016 devices are
1M x8 / 2M x8 CMOS Multi-Pur pose Fl ash (MPF) manu­factured with SST’s proprietary, high performance CMOS
SuperFlash technology. The split-gate cell design and thick
oxide tunneling injector attain better reliability and manufac­turability compared with alternate approaches. The
SST39LF080/016 write (Program or Erase) with a 3.0-3.6V
power supply. The SST39VF080/016 write (Program or
Erase) with a 2.7-3.6V power supply. They conform to
JEDEC standar d pino uts f or x8 me mories .

Featuring high p erformance Byte-Program, the SST 39LF/
VF080 and SST39LF/VF016 devices provide a typical
Byte-Program time of 14 µsec. The devices use Toggle Bit
or Data# Polling to indicate the completion of Program
operation. To protect against inad vertent write, they have
on-chip hardware and So ftware Data Prot ection s chem es.
Designed, manufactured, and tested for a wide spectrum of
applications, these devices are offered with a guaranteed
endurance of 10,000 cycles. Data retention is rated at
greater th an 10 0 years .

The SST39LF/VF080 and SST39LF/VF016 devices are
suited for applications that require convenient and econom­ical updating of program, configuration, or da ta memory.
For all system applicati ons, they significantly improve per­formance and reliability , while lowering power consumption.

They inherently use less energy during Erase and Program
than alternati ve flash technologies. The total energy con­sumed is a function of the applied voltage, current, and
time of application. Since for any given voltage range, the
SuperFlash techn ology uses less current to pr ogram and
has a shorter erase time, the total energy consumed during
any Erase or Program operation is less than alternative
flash technolog ies . They also im prov e f le xibilit y while l ow er­ing the cost for program, data, and conf iguration storage
applications.

The SuperFlash te ch no logy pr ovid es fi xed Erase an d P r o­gram times, independent o f the num be r of Erase/ Pro gram
cycles that have occurred. Therefore the system software
or hardware does not have to be modified or de-rated as is
necessary with alternative flash technologies, whose Erase
and Program times inc rease with accumul ated Erase/P ro­gram cycles .

To meet high density, surface mount requirements, the
SST39LF/VF080 a nd SST39LF/VF016 are offered in 40­lead TSOP and 48-ba ll TFBGA packaging. Se e Figures 1
and 2 for pinouts.

SST39LF/VF080 / 0163.0 & 2.7V 8Mb / 16Mb (x8) MPF memories

2

Data Sheet

8 Mbit / 16 Mbit Multi-Purpose Flash

SST39LF080 / SST39LF016 / SST39VF080 / SST39VF016

©2001 Silicon Storage Technology, Inc. S71146-03-000 6/01 396

Device Operation

Commands are used to initiate the memory operation func­tions of the device. Commands ar e written to the device
using standard mi croprocessor write sequen ces. A com­mand is written by asse r ting WE# low whil e keeping CE#
low. The address bus is latched on the falling edge of WE#
or CE#, whichever occurs last. T he data bus is latche d on
the rising edge of WE# or CE#, whichever occurs first.

The SST39LF/VF080 and SST39LF/VF016 also have the
Auto Low Power mode which puts the device in a near
standby mode after da ta has been accessed with a valid
Read operation. This reduces the I

DD

active read current
from typically 15 mA to typically 4 µA. The Auto Low P o wer
mode reduces the typical I

DD

active read current to the
range of 1 mA/MHz of read cycle time. The device exits the
Auto Low Power mode with any addres s transi tion o r con­trol signal transition used to initiate another Read cycle,
with no access time penalty. Note that the device does not
enter Auto Low Power mode after power-up with CE# held
steadily low until the first address transition or CE# is driven
high.

Read

The Read operation of the SST39LF/VF080 and
SST39LF/VF016 is controlled by CE# and OE#, both have
to be low for the system to obtain dat a from the outputs.
CE# is used for device selection. Whe n CE# is high, the
chip is dese lected and onl y standby power is cons umed.
OE# is the output control and is used to gate data from the
output pins. The data bus is in high impedance state when
either CE# or OE# is hi gh. Refer to the Rea d cycle t iming
diagram for further details (Figure 3).

Byte-Program Operation

The SST39LF/VF080 and SST39LF/VF016 are pro­grammed on a byte-by-byte basis. Before programming,
one must ensure that the sector, in which the byte which is
being programmed exists, is fully erased. The Program
operation consists of three steps. The first step is the three­byte load sequence for Software Data Protection. The sec­ond step is to load byte address and byte data. Dur i ng th e
Byte-Program operation, the addresses are latched on the
falling edge of either C E# or WE#, w hichever occurs last.
The data is latched on the rising edge of either CE# or
WE#, whichever occurs first. The third step is the inter nal
Program operation which is initiated after the rising edge of
the fourth WE# or CE#, whichever occurs first. The Pro­gram operation, once initiated, will be completed within 20
µs. See Figures 4 and 5 for WE# and CE# controlled Pro­gram operation timing diagrams and Figure 16 for flow­charts. Dur in g the P rogram operat ion, th e only valid reads

are Data# Polling and Toggle Bit. During the inte rnal Pro­gram operation, the host is free to perform additional tasks.
Any commands issued during the internal Program opera­tion are ignored.

Sector/Block-Erase Operation

The Sector- (or Block-) Erase operation allows the system
to erase the device on a sector-by-sector (or block-by­block) basis. The SST39LF /VF080 and SST39LF/VF016
offer both Sect or- Era se an d Block-Eras e mo de. Th e sec tor
architecture is based on uniform sector size of 4 KByte.
The Block-Erase mode is based on uniform block size of
64 KByte. The Secto r-Erase operation is ini tiated by exe­cuting a six-byte-command sequence with Sector-Erase
command (30H) and sector address (SA) in the last bus
cycle. The Block-Erase operation is initiated by executing a
six-byte-command seq uence with Block-Erase command
(50H) and block address (BA ) in the last bus cycle. The
sector or block address is latched on the falling edge of the
sixth WE# pulse, while the command (30H or 50H) is
latched on the rising edge of the sixth WE# pulse. The
internal Era se operation begin s after t he sixth W E# puls e.
The End-of-Erase operation can be determined using
either Data# Polling or Toggle Bit methods. Se e Figures 9
and 10 for timing waveforms. Any commands issued during
the Sector- or Block-Erase operation are ignored.

Chip-Erase Operation

The SST39LF/VF080 and SST39LF/VF016 provide a
Chip-Erase operation, wh ich allows the user to erase the
entire memory array to the “1” state. This is useful when the
entire device must be quickly erased.

The Chip-Erase operation is initiated by executing a six
byte command sequence with Chip-Erase command (10H)
at address 5555H in the last byte sequence. The Eras e
operation begins with the rising edge of the sixt h WE# or
CE#, whichever occurs first. During the Erase operation,
the only valid read is T oggle Bit or Data# Polling. See Table
4 for the command sequence, Figure 8 for timing diagram,
and Figure 19 for the flowchart. Any commands issued dur­ing the Chip-Erase operation are ignored.

Write Operation Status Detection

The SST39LF/VF080 and SST39LF/VF016 provide two
software means to detect the completion of a write (Pro­gram or Erase) cycle, in order to optimize the system Write
cycle time. The software detection includes two status bits:
Data# Polling (DQ

7

) and Toggle Bit (DQ6). The End-of-Write
detection mode is enabled after the rising edge of WE#,
which initiates the internal Program or Erase operation.

Data Sheet

8 Mbit / 16 Mbit Multi-Purpose Flash
SST39LF080 / SST39LF016 / SST39VF080 / SST39VF016

3

©2001 Silicon Storage Technology, Inc. S71146-03-000 6/01 396

The actual completion of the nonvolatile write is asynchro­nous with the system ; therefore, either a Data# Polling or
Toggle Bit read may be simultaneous with the c ompletion
of the Write cycle. If this occurs, the system may possibly
get an erroneous result, i.e., valid data may appear to con­flict with either DQ

7

or DQ6. In order to prevent spurious
rejection, if an erroneous result occurs, the software routine
should include a loop to read the accessed location an
additional two (2) times. If bo th reads are valid, then the
device has completed the Write cycle, otherwise the rejec­tion is valid.

Data# Polling (DQ7)

When the SST39LF/VF080 and SST39LF/VF016 are in
the internal Program operation, any attempt to read DQ

7

will produce the co mplement of the true data. Once th e
Program operation is completed, DQ

7

will produce true
data. The device is then ready for the next operation. Dur­ing intern al Erase ope ration, any atte mpt to re ad DQ

7

will
produce a ‘0’. Once the inter nal Erase operation is com-
pleted, DQ

7

will produce a ‘1’. The Data# Polling is valid
after the risin g e dge of four t h W E# (or CE # ) pul se for Pro­gram operation. For Sector-, Block- or Chip-Erase, the
Data# Polling is valid after the rising edge of si x th WE # ( or
CE#) pulse. See Figure 6 for Data# Polling timing dia gram
and Figure 17 for a flowchart.

Toggle Bit (DQ6)

During the inter nal Program or Erase ope ration, any con­secutive attempts to read DQ

6

will produce alter nating 1s
and 0s, i.e., toggling between 1 and 0. W hen the internal
Program or Erase operat ion is c omplete d, the DQ

6

bit will
stop toggling. The device is the n re ady for the next ope ra­tion. The Toggle Bit is valid after the rising edge of fourth
WE# (or CE#) pulse for Program operat ion. For Sector-,
Block-, or Chip-Erase, the T oggle Bit is valid after the rising
edge of sixth WE# (or CE#) pulse. See Figure 7 for Toggle
Bit timing diag ram and Figu re 17 f or a fl owc hart.

Data Protection

The SST39LF/VF080 and SST39LF/VF016 provide both
hardware and software features to protect nonvolatile dat a
from inadvertent writes.

Hardware Data Protection

Noise/Glitch Protection: A WE# or CE# pulse of l ess th an 5
ns will not initiate a Write cycle.

V

DD

Power Up/Down Detection: The Write operation is

inhibited when V

DD

is less than 1.5V.

Write Inhibit Mode:

Forcing OE# low, CE# high, or WE#
high will inhibit the W r it e operation. This prevents inadvert­ent writes during p ow er-u p or po wer- dow n.

Software Data Protection (SDP)

The SST39LF/VF080 and SST39LF/VF016 provide the
JEDEC approved Software Data Protecti on schem e for all
data alteration operations, i.e., Program and Erase. Any
Program operation req uires t he inc lusion of the thr ee-byte
sequence. The three-byte load sequence is used to initiate
the Program operation, p roviding optimal protection from
inadvertent Write operations, e.g., during the system
power-up or power-down. Any Erase operation requires the
inclusion of si x-byte sequence. The SS T39LF/VF080 an d
SST39LF/VF016 devices are shipped with the Software
Data Protection permanently enabled. See Table 4 for the
specific software command codes. During SDP command
sequence, invalid commands will abo r t the device to read
mode within T

RC

.

Common Flash Memory Interface (CFI)

The SST39LF/VF080 and SST39LF/VF016 also contain
the CFI information to describe the characteri stics of the
device. In order to enter the CFI Quer y mode, the system
must write three-byte sequence, same as product ID entry
command with 98H (CFI Query command) to address
5555H in the la st byte sequenc e. Once the device en ters
the CFI Query mode, the system can read CFI data at the
addresses given in Tables 5 through 8. The system must
write the CFI E xit co mmand t o retur n to Read mo de from
the CFI Query mode.

4

Data Sheet

8 Mbit / 16 Mbit Multi-Purpose Flash

SST39LF080 / SST39LF016 / SST39VF080 / SST39VF016

©2001 Silicon Storage Technology, Inc. S71146-03-000 6/01 396

Product Identification

The Product Identification mode identifies the device as the
SST39LF080, SST39VF080, SST39LF016, and
SST39VF016 and manufacturer as SST. This mode may
be accessed by software o perations. Users may use the
Software Product Identification operation to identify the part
(i.e., using the device ID) when usi ng multipl e manufactur­ers in the same socket. For details, see Table 4 for software
operation, Figure 11 for the Software ID Entry a nd Read
timing diagram and Figure 18 for the Software ID Entry
command sequence flo wchart.

Product Identification Mode Exit/
CFI Mode Exit

In order to return to the standard Read mode, the Software
Product Identifica tion mode must be exited. Exi t is acco m­plished by issuing the Software ID Exit command
sequence, which returns the device to the Read operation.
This command may also be used to reset the device to the
Read mode after any inadvertent transient condition that
apparently causes the device to behave abnorma lly, e.g.,
not read correctly. Please note that the Soft ware ID Exit/
CFI Exit command is ignored during an internal Program or
Erase operation. See Table 4 for software command
codes, Figure 13 for timing waveform and Figure 18 for a
flowchart.

TABLE 1: P

RODUCT IDENTIFICATION

Address Data

Manufacturer’s ID 0000H BFH
Device ID

SST39LF/VF080 0001H D8H
SST39LF/VF016 0001H D9H

T1.2 396

Y-Decoder

I/O Buffers and Data Latches

396 ILL B1.2

Address Buffer & Latches

X-Decoder

DQ7 - DQ

0

Memory
Address

OE#

CE#

WE#

SuperFlash

Memory

Control Logic

FUNCTIONAL BLOCK DIAGRAM

Data Sheet

8 Mbit / 16 Mbit Multi-Purpose Flash
SST39LF080 / SST39LF016 / SST39VF080 / SST39VF016

5

©2001 Silicon Storage Technology, Inc. S71146-03-000 6/01 396

FIGURE 1: PIN ASSIGNMENTS FOR 40-LEAD TSOP

FIGURE 2: P

IN ASSIGNMENTS FOR 48-BALL TFBGA

SST39LF/VF080 SST39LF/VF016

A16
A15
A14
A13
A12
A11

A9
A8

WE#

NC
NC
NC

A18

A7
A6
A5
A4
A3
A2
A1

A16
A15
A14
A13
A12
A11

A9
A8

WE#

NC
NC
NC

A18

A7
A6
A5
A4
A3
A2
A1

1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20

A17
V

SS

NC
A19
A10
DQ7
DQ6
DQ5
DQ4
V

DD

V

DD

NC
DQ3
DQ2
DQ1
DQ0
OE#
V

SS

CE#
A0

40

39

38

37

36

35

34

33

32

31

30

29

28

27

26

25

24

23

22

21

396 ILL F01.2

Standard Pinout

T op Vie w

Die Up

SST39LF/VF160 SST39LF/VF080

A17
V

SS

A20
A19
A10
DQ7
DQ6
DQ5
DQ4
V

DD

V

DD

NC
DQ3
DQ2
DQ1
DQ0
OE#
V

SS

CE#
A0

A14

A9

WE#

NC
A7
A3

A13

A8
NC
NC

A18

A4

A15
A11

NC
NC
A6
A2

A16
A12

NC
NC
A5
A1

A17

A19
DQ5
DQ2
DQ0

A0

NC

A10

NC

DQ3

NC

CE#

A20
DQ6
V

DD

V

DD

NC

OE#

V

SS

DQ7
DQ4

NC
DQ1
V

SS

396 ILL F21.1

SST39LF/VF016

TOP VIEW (balls facing down)

6
5
4
3
2
1

A B C D E F G H

A14

A9

WE#

NC
A7
A3

A13

A8
NC
NC
A18

A4

A15
A11

NC
NC
A6
A2

A16
A12

NC
NC
A5
A1

A17

A19
DQ5
DQ2
DQ0

A0

NC

A10

NC

DQ3

NC

CE#

NC
DQ6
V

DD

V

DD

NC
OE#

V

SS

DQ7
DQ4

NC
DQ1
V

SS

396 ILL F20.1

SST39LF/VF080

TOP VIEW (balls facing down)

6
5
4
3
2
1

A B C D E F G H

6

Data Sheet

8 Mbit / 16 Mbit Multi-Purpose Flash

SST39LF080 / SST39LF016 / SST39VF080 / SST39VF016

©2001 Silicon Storage Technology, Inc. S71146-03-000 6/01 396

TABLE 2: PIN DESCRIPTION

Symbol Pin Name Functions

A

MS

1

-A

0

Address Inputs To provide memory addresses. During Sector-Erase AMS-A12 address lines w ill s ele ct the

sector. During Block-Erase A

MS-A16

address lines will select the block.

DQ

7

-DQ

0

Data Input/output To output data during Read cycles and receive input data during Write cycles.

Data is internally latched during a Write cycle.

The outputs are in tri-state when OE# or CE# is high.
CE# Chip Enable To activate the device when CE# is low.
OE# Output Enable To gate the data output buffers.
WE# Write Enable To control the Write operations.
V

DD

Power Supply To provide power supply voltage: 3.0-3.6V for SST39LF080/016

2.7-3.6V for SST39VF080/016

V

SS

Ground

NC No Connection Unconnected pins.

T2.3 396

1. AMS = Most significant address
A

MS

= A19 for SST39LF/VF080 and A20 for SST39LF/VF016

TABLE 3: OPERATION MODES SELECTION

Mode CE# OE# WE# DQ Address

Read V

IL

V

IL

V

IH

D

OUT

A

IN

Program V

IL

V

IH

V

IL

D

IN

A

IN

Erase V

IL

V

IH

V

IL

X

1

1. X can be VIL or VIH, but no other value.

Sector or Block address,
XXH for Chip-Erase

Standby V

IH

XXHigh Z X

Write Inhibit X V

IL

XHigh Z/ D

OUT

X

XXV

IH

High Z/ D

OUT

X
Product Identification
Software Mode V

IL

V

IL

V

IH

See Table 4

T3.4 396

Data Sheet

8 Mbit / 16 Mbit Multi-Purpose Flash
SST39LF080 / SST39LF016 / SST39VF080 / SST39VF016

7

©2001 Silicon Storage Technology, Inc. S71146-03-000 6/01 396

TABLE 4: SOFTWARE COMMAND SEQUENCE

Command
Sequence

1st Bus

Write Cycle

2nd Bus

Write Cycle

3rd Bus

Write Cycle

4th Bus

Write Cycle

5th Bus

Write Cycle

6th Bus

Write Cycle

Addr1Data Addr1Data Addr1Data Addr1Data Addr1Data Addr1Data

Byte-Program 5555H AAH 2AAAH 55H 5555H A0H WA

2

Data

Sector-Erase 5555H AAH 2AAAH 55H 5555H 80H 5555H AAH 2AAAH 55H SA

X

3

30H

Block-Erase 5555H AAH 2AAAH 55H 5555H 80H 5555H AAH 2AAAH 55H BA

X

3

50H
Chip-Erase 5555H AAH 2AAAH 55H 5555H 80H 5555H AAH 2AAAH 55H 5555H 10H
Software ID Entry

4,5

5555H AAH 2AAAH 55H 5555H 90H

CFI Query Entry

4

5555H AAH 2AAAH 55H 5555H 98H

Software ID Exit

6

/

CFI Exit

XXH F0H

Software ID Exit

6

/

CFI Exit

5555H AAH 2AAAH 55H 5555H F0H

T4.3 396

1. Address format A14-A0 (Hex),
Addresses A

15

- A19 can be VIL or VIH, but no other value, for the Command sequenc e for SST39LF/VF080.

Addresses A

15

- A20 can be VIL or VIH, but no other value, for the Command sequenc e for SST39LF/VF016.

2. WA = Program Byte address

3. SA

X

for Sector-Erase; uses AMS-A12 address lines

BA

X

, for Block-Erase; uses AMS-A16 address lines

A

MS

= Most significant address

A

MS

= A19 for SST39LF/VF080 and A20 for SST39LF/VF016

4. The device does not remain in Software Product ID Mode if powered down.

5. With A

MS-A1

=0; SST Manufacturer’s ID= BFH, is read with A0 = 0,

SST39LF/VF080 Device ID = D8H, is read with A

0

= 1

SST39LF/VF016 Device ID = D9H, is read with A

0

= 1

6. Both Software ID Exit operations are equivalent

TABLE 5: CFI QUERY IDENTIFICATION STRING1 FOR SST39LF/ VF080 AND SS T39LF/VF016

1. Refer to CFI publication 100 for more details.

Address Data Data

10H 51H Query Unique ASCII string “QRY”
11H 52H
12H 59H
13H 01H Primary OEM command set
14H 07H
15H 00H Address for Primary Extended Table
16H 00H
17H 00H Alternate OEM command set (00H = none exists)
18H 00H
19H 00H Address for Alternate OEM extended Table (00H = none exits)

1AH 00H

T5.3 396

8

Data Sheet

8 Mbit / 16 Mbit Multi-Purpose Flash

SST39LF080 / SST39LF016 / SST39VF080 / SST39VF016

©2001 Silicon Storage Technology, Inc. S71146-03-000 6/01 396

TABLE 6: SYSTEM INTERFACE INFORMATION FOR SST39VF 320/64 0

Address Data Data

1BH 27H

1

VDD Min (Program/Erase)

30H

1

DQ7-DQ4: Volts, DQ3-DQ0: 100 millivolts

1CH 36H V

DD

Max (Program/Erase)

DQ

7

-DQ4: Volts, DQ3-DQ0: 100 millivolts

1DH 00H V

PP

min. (00H = no VPP pin)

1EH 00H V

PP

max. (00H = no VPP pin)

1FH 04H Typical time out for Byte-Program 2

N

µs (24 = 16 µs)

20H 00H Typical time out for min. size buffer program 2

N

µs (00H = not supported)

21H 04H Typical time out for individual Sector/Bloc k -Er as e 2

N

ms (24 = 16 ms)

22H 06H Typical time out for Chip-Erase 2

N

ms (26 = 64 ms)
23H 01H Maximum time out for Byte-Program 2N times typical (21 x 24 = 32 µs)
24H 00H Maximum time out for buffer program 2N times typical
25H 01H Maximum time out for individual Sector/Block-Erase 2

N

times typical (21 x 24 = 32 ms)

26H 01H Maximum time out for Chip-Erase 2N times typical (21 x 26 = 128 ms)

T6.1 396

1. 0030H for SST39LF080/016 and 0027H for SST39VF080/016

TABLE 7: DEVICE GEOMETRY INFORMATION FOR SST39LF/VF080

Address Data Data

27H 14H Device size = 2

N

Bytes (14H = 20; 220 = 1 MBytes)
28H 00H Flash Device Interface description; 0000H = x8-only asynchronous interface
29H 00H
2AH 00H Maximum number of byte in multi-byte write = 2

N

(00H = not supported)
2BH 00H
2CH 02H Number of Erase Sector/Block sizes supported by device
2DH FFH Sector Information (y + 1 = Number of sectors; z x 256B = sector size)
2EH 00H y = 255 + 1 = 256 sectors (00FFH = 255)
2FH 10H
30H 00H z = 16 x 256 Bytes = 4 KBytes/sector (0010H = 16)
31H 0FH Block Information (y + 1 = Number of blocks; z x 256B = block size)
32H 00H y = 15 + 1 = 16 blocks (000FH = 15)
33H 00H
34H 01H z = 256 x 256 Bytes = 64 KBytes/block (0100H = 256)

T7.0 396