Siemens AR6181-MX, AR6182-MX Installation And Configuration Manual

AR6181-M

X

A

R6182-MX

Card reader AR6181-MX,
AR6182-MX

Installation and Configuration

6FL7170-8BK
6FL7170-8BL
RS485: CerPass- and UCI-Protocol
Clock/Data Interface: Omron and Wiegand

Fire & Security Products

Siemens Building Technologies

Liefermöglichkeiten und technische Änderungen vorbehalten.
Data and design subject to change without notice. / Supply subject to availability.
© 2004 Copyright by
Siemens Building Technologies AG

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oder außerhalb des Zweckes verwenden, zu dem es ihm übergeben worden ist.

We reserve all rights in this document and in the subject thereof. By acceptance of the document the recipient acknowledges these rights
and undertakes not to publish the document nor the subject thereof in full or in part, nor to make them available to any third party without our
prior express written authorization, nor to use it for any purpose other than for which it was delivered to him.

Thank you for deciding to purchase the AR618x-MX.
We hope you are completely satisfied with this product. If you have any questions
or comments please feel free to contact your local SIEMENS branch, who will be
happy to help.

The ID card readers AR6181-MX and AR6182-MX (with keypad) are new proximity
ID card readers in a Square housing, part of the new Access reader range.
The readers read proximity ID cards of 13.56 MHz technologies:

ISO14443 Type A - like Mifare® 1k, 4k or UltraLight, my-D proximity (SLE55Rxx),

ISO14443 Type B - like my-C (SLE66CL160S) and

ISO15693 - like my-D vicinity, I-Code SLI, TagIT-HFI.

or the personalised ID number out of a sector/block (Mifare) or a public block
(Mifare UltraLight, my-D). The card number will be transmitted to the Access
control system for processing.

This manual provides a detailed function overview.

Contents

1 Approval...................................................................................................5

2 Safety regulations and warnings...........................................................5

3 General notes ..........................................................................................6

4 Delivery volume.......................................................................................6

5 Technical specifications ........................................................................7

6 Installation ............................................................................................... 8

6.1 Opening the housing.................................................................................8

6.2 Flush mounting..........................................................................................9

6.3 Surface mounting....................................................................................10

6.4 Connecting the reader, display elements ...............................................12

6.4.1 Power supply...........................................................................................13

6.4.2 RS485 interface ......................................................................................13

6.4.3 Clock/Data interface................................................................................13

7 DIP switch settings ...............................................................................14

7.1 Address setting for RS485 bus operation, 2-wire ...................................14

7.2 Setting the address (Clock/Data)............................................................15

7.3 Communication interface and protocol selection ....................................15

7.4 Information to be read out of cards.........................................................16

8 Transponders / ID cards.......................................................................18

8.1 Qualified transponder types (ID cards) ...................................................19

8.1.1 ISO14443A Proximity read range ...........................................................19

8.1.2 ISO14443A+B Proximity read range.......................................................19

8.1.3 ISO15693 Vicinity read range.................................................................20

8.2 Information on transponder.....................................................................20

8.2.1 Serial number.......................................................................................... 21

8.2.2 ID number ...............................................................................................21

8.3 Data formats of the Transponder............................................................22

8.3.1 BCD format .............................................................................................22

8.3.2 ASCII format............................................................................................23

8.3.3 Wiegand format....................................................................................... 23

9 Card reader configuration....................................................................24

9.1 Defining parameters................................................................................25

9.2 Launching the terminal program .............................................................25

9.3 Configuration mode of the Terminal program .........................................27

9.3.1 Commands..............................................................................................29

9.3.1.1 Firmware, new load.................................................................................29

9.4 Reader interface......................................................................................32

9.5 Output data formats ................................................................................32

10 Configuration parameters ....................................................................33

10.1 Config or ConfigCard parameters...........................................................33

10.2 Combination options ...............................................................................37

10.2.1 Serial number RS485 – CerPass reader protocol .................................37

10.2.2 Serial number RS485 – UCI reader protocol .........................................37

10.2.3 Serial number Clock / Data – Omron interface ......................................37

10.2.4 Serial number Clock / Data – Wiegand interface...................................38

10.2.5 ID number – ASCII format RS485 – CerPass reader protocol ..............38

10.2.6 ID number – ASCII format RS485 – UCI reader protocol......................38

10.2.7 ID number – BCD format RS485 – CerPass reader protocol .................39

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10.2.8 ID number – BCD format RS485 – UCI reader protocol.........................39

10.2.9 ID number – BCD/ASCII format Clock / Data: Omron interface .............39

10.2.10 ID number – Wiegand format RS485 – CerPass reader protocol...........40

10.2.11 ID number – Wiegand format RS485 – UCI reader protocol ..................40

10.2.12 ID number – Wiegand format Clock/Data: Wiegand interface................41

10.2.13 ID number – Wiegand format Clock/Data: Omron interface ...................41

10.3 PIN code..................................................................................................42

10.3.1 RS485 – CerPass reader protocol ..........................................................42

10.3.2 RS485 – UCI reader protocol..................................................................43

10.3.3 Clock / Data – Omron interface...............................................................43

10.3.4 Clock / Data – Wiegand interface ...........................................................43

10.4 Defining reading keys with Mifare Standard 1k and 4k...........................44

11 Appendix................................................................................................45

11.1 Definition of Clock/Data interfaces..........................................................45

11.1.1 Omron 5 bit, Magstripe Track II...............................................................45

11.1.2 Wiegand ..................................................................................................45

11.2 Dimensions for flush mounting................................................................46

11.3 Dimensions for surface mounting with distance frame ...........................47

11.4 Addressing / Address setting: Mifare 1k .................................................48

11.5 EC Declaration of Conformity..................................................................49

12 Keyword index.......................................................................................50

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Approval

1 Approval

If used according to the instructions, this radio system meets the basic
requirements of article 3 and the remaining applicable conditions of the R&TTE
directive (1999/5/E6) of March 1999.

Equipment Classification according to ETSI EN 300 330: Class 2

FCC ID: PJMCPR02

This device complies with Part 15 of the FCC Rules. Operation is subject to the
following two conditions:
(1) this device may not cause harmful interference, and
(2) this device must accept any interference received, including interference that
may cause undesired operation.

Unauthorized modifications may void the authority granted under Federal
Communications Commission Rules permitting the operation of this device.

2 Safety regulations and warnings

 The unit must only be used for the purpose intended by the manufacturer.
 The installation instructions must be kept to hand and made available to every

user.

 Unauthorized changes and the use of spare parts and accessories which are not

sold or recommended by the manufacturer of the unit could cause fire, electric
shock or injury. Therefore, such measures will result in a renunciation of liability
and the manufacturer will not accept any guarantee claims.

 The manufacturer's guarantee terms in the version valid at the time of the sale

are applicable to the unit. No liability will be accepted for unsuitably or incorrectly
set parameters – whether automatic or manual – or for inappropriate use of the
unit.

 All repairs must be carried out by the manufacturer.
 The user is responsible for ensuring that the unit is set up and connected in

accordance with the recognized technical regulations in the country of
installation and any other guidelines valid in the relevant region.

 Before opening the unit, always switch off the power supply and take

measurements to ensure that there is no power to the unit.

 If an operating display goes out, this does not necessarily mean that the unit is

disconnected from the mains and has no power. If you are working on an open
device, remember that live components may be exposed.

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General notes

3 General notes

The data transmission of the system from the user cards to the card readers is
based on a electromagnetic field, which is created around the aerial of the card
reader. If the ID card is approximated to the electromagnetic field of the reader
aerial, it is supplied with energy and sends its personalised data. The data is
received by the reader aerial.

The reading range of the card readers AR618x-MX, depending on the kind of the
arrangement and material the reader is mounted on, is up to 70 mm.

The kind of transponder used (ID card, key fob, etc.) also has an important
influence on the reading distance.

Mind that the card readers are not installed near computer terminals, TV sets, etc.
as these devices might also affect the reading range. If the card reader is mounted
on metal walls or metallized glass surfaces, the distance frame which is included in
the delivery should be used. Please take into account the reading range will
thereby be reduced. More information can be found in chapter 6 Installation.

Installation according to the type of protection IP 65 (using the gaskets which are
included in the delivery). Avoid installing the reader in places where it is subject to
direct sunlight.

The reader has one multicolour LED for the colours yellow, green and red and an
internal buzzer.

4 Delivery volume

1 x housing; upper part with reader electronic and front foil

1 x housing; lower part with connection board

1 x distance frame

1 x accessory bag

1 x installation instructions

1 x repair form

3 x gasket

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Technical specifications

5 Technical specifications

Housing PC/ABS plastic
Colour
Top section of housing Similar to RAL 9006 (white aluminium)
Bottom section of housing Similar to RAL 9006 (white aluminium)
Weight Approx. 120 g
Degree of protection IP 65
Power supply 12 to 24 V AC/DC

Min. 10.2 V to max. 27.6 V
Power consumption Max. 3 W
Temperature range -20 to +60 °C
Relative air humidity 95% (no dew formation)
Antenna Integrated
Operating frequency 13.56 MHz
Qualified transponders

ISO14443A:

Mifare Standard 1k and 4k (UID, S/B, MAD),

Mifare UltraLight (UID, B), Mifare DESfire (UID),

my-D proximity (UID, B)

ISO14443B:

my-C (SLE66CL160S) (UID)

ISO15683:

my-D vicinity, I-Code SLI, TagIT HFI,

STM LRI512 (all UID)
Transducer

1 x multicolour LED (red, green, orange)

1 x buzzer
Interfaces

RS485 2-wire (9600 Baud, 8 data bits,

1 stop bit, no parity)

Protocols: UCI, CerPass reader protocol

Clock/Data, unidirectional (CLS, CLOCK, DATA) –

OMRON emulation, Wiegand emulation

DIP switch

8 (address setting and operating mode)
Digital Inputs

In conjunction with Clock/Data interface

 IN 1: LED green, short beep

 IN 2: LED red, long beep

EEPROM 10,000 write cycles

AR6181-MX 6FL7170-8BK

without keypad

AR6182-MX 6FL7170-8BL

with keypad (number 0-9, C and E)

Legend:

UID – Unique card number,

S/B – data out of a sector/block,

B – data out of a block,

MAD – Mifare Application Directory

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Installation

6 Installation

The reader is designed to be wall-mounted on 60 mm flush-mounting boxes. For
surface mounting, the bottom section of the housing can be affixed to the distance
frame supplied.

Notes:

 The reader should not be mounted directly onto conductive materials, such as metal surfaces, metal

frames (reinforcement) or metal-plated surfaces, as these surfaces will reduce the reader's range.
The clearance to such surfaces should be at least 30 cm.

 If the unit has to be mounted onto a metal surface, the distance frame supplied can be used to

maintain the minimum clearance.

 The distance between readers of the same design should not be less than 30 cm.
 Before final installation, the planned installation site should be checked for suitability.
 You can tell the direction of the distance frame or the bottom section of the housing from the

inscription „TOP  “. The arrow must point upwards!

TOP

Å

Fig. 1 Installation direction

6.1 Opening the housing

If you attach the top section of the housing to the bottom section, it slots into place.
This means you should proceed as follows when opening the housing:

 Unscrew the safety screw (1)
 Insert a screwdriver into the two points on the side of the reader housing

between the top and bottom sections of the housing (2).

 Remove the top section of the housing from the bottom section.

Fig. 2 Opening the housing

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Installation

6.2 Flush mounting

The unit should be installed on a surface that is as even as possible.

Procedure

 Slot the connection board into the bottom section of the housing with the

terminals facing downwards. To do this gently push the locating hooks apart with
your fingers.

 Connect the cable to the terminal strip in the bottom section of the housing

(see chapter „5.1 Connecting the reader“).

 Plug the top section onto the bottom section of the housing. In doing so, insert

the male connector of the reader electronics cleanly into socket connector X3 on
the terminal board!

 Do not mount the unit to the wall before you have checked the set-up

works.

 Remove the top section of the housing from the bottom section.
 Screw the bottom section of the housing incl. the snapped terminal board onto

the base, using 3 x 16 mm self-tapping screws.

 Plug the top section onto the bottom section of the housing. In doing so, insert

the male connector of the reader electronics cleanly into socket connector X3 on
the terminal board!

 Screw in the safety screw on the underneath of the bottom section of the

housing.

Note:
The maximum torque of the safety screw is 1.5 Nm.

Socket connector X3

Fig. 3 Back view of the bottom section of the housing

with the terminal board snapped in

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Installation

6.3 Surface mounting

 The unit should be installed on a surface that is as even as possible.
 Create openings for the lead in the distance frame and pull the lead through.
 Screw the distance frame onto the base.

Procedure

 Slot the connection board into the bottom section of the housing with the

terminals facing downwards. To do this gently push the locating hooks apart with
your fingers.

 Connect the cable to the terminal strip in the bottom section of the housing

(see chapter „5.1 Connecting the reader“).

 Plug the top section onto the bottom section of the housing. In doing so, insert

the male connector of the reader electronics cleanly into socket connector X3 on
the terminal board!

 Do not mount the unit to the wall before you have checked the set-up

works.

 Remove the top section of the housing from the bottom section.
 Screw the bottom section of the housing incl. the snapped terminal board onto

the distance frame using 3 x 16 mm self-tapping screws.

 Plug the top section onto the bottom section of the housing. In doing so, insert

the male connector of the reader electronics cleanly into socket connector X3 on
the terminal board!

 Screw in the safety screw on the underneath of the bottom section of the

housing.

Mounting in conformity with IP 65

In order to mount the reader, regarding the IP 65 conditions, the following
instructions are to be followed.

Three special gaskets are enclosed in the reader package.

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Gasket 1

(one-sided self-adhesive)

Gasket 3

Gasket 2

(one-sided self-adhesive)

Fig. 4 Three gaskets in the reader package

Usage

Gasket 1: Between reader and mounting surface, with or without distance frame

Gasket 2: Between housing base and distance frame

Gasket 3: Gasket for safety screw

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Installation

Installation of the Square reader without distance frame

For an installation without

distance frame the gasket 1 has to be stuck on the back
of the housing base. The position of the slits in the gasket has to correspond to the
position of the screw holes in the housing.

Fig. 5 Installation with gasket 1

Installation of the Square housing with

distance frame

For an installation with

distance frame the gasket 1 is to be stuck on the back of
this distance frame. The position of the slits in the gasket has to correspond to the
position of the screw holes in the housing. The gasket 2 has to be stuck in the
distance frame.

Fig. 6 Installation with gasket 1 and 2

Gasket for the safety screw

Whether the reader will be mounted with or without distance frame, the gasket 3
has to be used in both cases. The accessory pack includes one gasket 3 as a
reserve.

Fig. 7 Use of gasket 3

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Installation

6.4 Connecting the reader, display elements

The reader is connected using the terminal board at the bottom section of the
housing.

Fig. 8 Terminal board

Terminal Function

Strip Description AR6181-MX/AR6182-MX card reader

RS485 Bus Clock/Data interface

Omron Wiegand

X2 + / ~ Power supply

- / ~ Power supply
CLS *) CLS
COM *)
NO *)
GND *) internal GND
R/A RS485 - B
T/B RS485 - A

X1 CLK *) Clock D0

DAT *) Data D1
IN1 *) LED green, Buzzer short
IN2 *) LED red, Buzzer long

*) Terminal must not be used, risk of damage!

Tab. 1 Terminal allocation on the terminal board

LED

red Access denied
yellow Reader connected to power supply
green Access permitted

yellow,
flashing

Reader connected to power supply; reader will not be polled

LED - when Clock/Data interface is used

red Control via digital input IN2; e.g. access denied
green Control via digital input IN1; e.g. access permitted
yellow Reader connected to power supply

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Installation

6.4.1 Power supply

The power is supplied through terminals [+ / ~] and [- / ~]. The unit can run off
12 to 24 V either AC or DC. For DC voltage supply, either polarity can be selected.

Notes:

 The length of cable between the power pack and the reader should be kept as short as possible.

The lead must not be laid parallel to other energy supply and low voltage cables.

 The minimum supply at the unit must be 10.2 V.

6.4.2 RS485 interface

With RS485 data buses it can be necessary to use terminating resistors. These
checks should be made for each installation. Generally, a terminating resistor is
only required at the end of the bus, i.e. on the last unit. In order to do this, a bridge
needs to be set up between terminals 1 and 2 of terminal X2 (see Fig. 11).

To operate the bus, you need a controller with a terminating resistor and active
termination (see below).

Controller

without terminating resistor

R/A T/B

AR 618x-MX

(with active termination)

with terminating resistor

B

A

X

2

AR 618x-MX

X

2

AR 61 8x-MX

X

2

Fig. 9 Operating a bus with an RS485 interface

6.4.3 Clock/Data interface

The reader connection using the Clock/Data interface has to be done according to
figure below. The cable length is limited to a maximum of 100 cm.

UCI-Box

or

DCU-3

DAT / D1

CLK / D0

AR6181-MX

GND / +V

GND / +V

CLOCK
DAT

CLS

CLS

IN1 / IN2

IN1 / IN2

Fig. 10 Connection using Clock/Data interface

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DIP switch settings

7 DIP switch settings

X1:

Terminal strip

X2:

RS485: Terminating resistor
(100 Ω active: 1-2 / inactive: 2-3)
Default Jumper setting: 2-3

X3:

RS485: Termination against GND
(active: 1-2 / inactive 2-3)
Default Jumper setting: 2-3

X4:

RS485: Termination against +5 V
(active: 2-3 / inactive 1-2)
Default Jumper setting: 1-2

J1, J2,
X7:

Should not be assigned or shorted (will lead to
malfunction or even
destruction of the card reader)

X5:

Connector for keyboard

Fig. 11 Switch positions

7.1 Address setting for RS485 bus operation, 2-wire

All card readers are issued with an individual address as shown in table 2.
The address option of the reader interface and door controller must be considered.

Bus address DIP 1 DIP 2 DIP 3 DIP 4

0-15 1-16

off off off off

0 1

off off off

on

1 2

off off

on

off

2 3

off off

on on

3 4

off

on

off off

4 5

off

on

off

on

5 6

off

on on

off

6 7

off

on on on

7 8

on

off off off

8 9

on

off off

on

9 10

on

off

on

off

10 11

on

off

on on

11 12

on on

off off

12 13

on on

off

on

13 14

on on on

off

14 15

on on on on

15 16

Tab. 2 Bus address: addressing taking into account the interface

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DIP switch settings

 If the bus address is set for CerPass reader protocol,

the reader addresses 1 . . . 16 can be used.

 If the bus address is set for UCI reader protocol,

only the reader addresses 1 . . . 4 can be used.

The method of address counting and addressing (number of readers to be connected) depends on the
controller / reader interface used and must be taken into account.

7.2 Setting the address (Clock/Data)

There is no need to select a reader address when the Clock/Data interface is used.

The Clock/Data interface allows only one reader to connect with the interface.

7.3 Communication interface and protocol selection

The communication interface has to be selected either to communicate with
intelligent controllers or via RS485 bus to connect to a reader interface or
Clock/Data interface.

Within the communication interface there are different protocols selectable.

DIP 4 DIP 5 DIP 6 Communication interface Protocol

x off off RS485 bus operation UCI reader protocol
x off

on

RS485 bus operation CerPass reader protocol

off

on

off Clock/Data interface Wiegand

on on

off Clock/Data interface Omron (Magstripe Track II)

x

on on

RS485 point-to-point Configuration mode

x – don’t care, see tab. 2

Tab. 3 Selection of communication interface

Note:
In RS485 bus operation, DIP 4 is LSB of the reader's bus address.

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DIP switch settings

7.4 Information to be read out of cards

According to the communication interface, the information to be read out of the
access cards has to be selected.

Important:

Please ensure that the number of positions analysed and the format of the interface connected can be
processed.

DIP 7 DIP 8 Information to be read Card type

off off Serial number ISO14443A+B, ISO15693

CerPass protocol (RS485) UID 13 characters card information, decimal equivalent,

transmitted as a ASCII format

UCI protocol (RS485) UID 13 digits card information, decimal equivalent,

transmitted as a 5 bit ABA format or a 7 bit SIPASS ASCII format

Clock/Data: Omron UID 13 digits card information, decimal equivalent,

transmitted as a 5 bit ABA format

Clock/Data: Wiegand UID 13 digits card information, decimal equivalent

transmitted as a BCD format (4 bit per digit)
No real and compliant Wiegand format, data is BCD coded and transmitted via Wiegand

interface

Please note:

Serial number of the transponder chips of the respective protocol. For further
information please refer to 8.1 Qualified transponder types (ID cards).

DIP 7 DIP 8 Information to be read Card type

off

on

ID number Wiegand format compliant ISO14443A

CerPass protocol (RS485) ID number

Wiegand format

Interpretation of Wiegand format to max. 13 characters,
transmitted as an ASCII format

UCI protocol (RS485) ID number

Wiegand format

Interpretation of Wiegand format to max. 13 digits / characters,
transmitted as a 5 bit ABA format or a 7 bit SIPASS ASCII format

Clock/Data: Omron ID number

Wiegand format

Interpretation of Wiegand format to max. 13 characters,
transmitted as a 5 bit ABA format

Clock/Data: Wiegand ID number

Wiegand format

1:1 transmission of the Wiegand formatted data

Please note:

Within this selection only ISO14443A cards with personalized application data
within a sector/block or a block will be read.

The ID number is an information written by the user into the read/write area of the
qualified transponders/cards.

In this case, the ID number is written according to the Wiegand format rules
(26 or 37 bit Wiegand format, others may be possible).

No reaction or malfunction will be at the reader AR6181-MX if other coded cards
are presented.

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DIP switch settings

DIP 7 DIP 8 Information to be read Card type

on

off

ID number, BCD (4 bit) or

ASCII (7 bit) coded data

ISO14443A

CerPass protocol (RS485) ID number

ASCII format
(7 bit)

Max. 16 characters of information,
transmitted as a 7 bit ASCII format

UCI protocol (RS485) ID number

BCD-format
(4 bit)

Max. 32 digits of information,
transmitted as a 5 bit ABA format

Clock/Data: Omron ID number

BCD (4 bit) or
ASCII (7 bit)
format

Transmitted as every 4 bit (half byte) in a 5 bit ABA format. ASCII formatted
data will be transmitted in two halves (high/low half byte of ASCII character)
means as two digits per char.

Clock/Data: Wiegand ID number

BCD (4 bit) or
ASCII (7 bit)
format

Transmitted without conversion as bit stream of coded data

Please note:

Within this selection only ISO14443A cards with personalized application data
within a sector/block or a block will be read.

The ID number is an information written by the user into the read/write area of the
qualified transponders / cards (Write areas sector/block or block within qualified
transponders / cards).

No reaction or malfunction will be at the reader AR6181-MX if other coded cards
are presented.

DIP 7 DIP 8 Information to be read Card type

on on

ID number, BCD (4 bit) or SIPASS (7 bit) coded data ISO14443A

CerPass protocol (RS485) ID number

BCD format
(4 bit)

Max. 16 numeric digits (value 0 . . . 9) of information,
transmitted as a 7 bit ASCII format;
Each digit is send as one numeric ASCII character

UCI protocol (RS485) ID number

ASCII format
(7 bit)

Max. 16 characters of information,
transmitted as a 7 bit ASCII format,
Option: Conversion of older SIPASS card format

Clock/Data: Omron Impermissible

Clock/Data: Wiegand Impermissible

Please note:

Within this selection only ISO14443A cards with personalized application data
within a sector/block or a block will be read.

The ID number is an information written by the user into the read/write area of the
qualified transponders / cards (write areas sector/block or block within qualified
transponders / cards).

No reaction or malfunction will be at the reader AR6181-MX if other coded cards
are presented.

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Transponders / ID cards

8 Transponders / ID cards

The configuration settings offer users numerous options for reading ID card data in
different formats and for the transfer of data to the reader using the existing
interface.

The procedure to determine the required configuration parameters can be carried
out based on the following order of events.

Which 13.56 MHz transponder ?
(Card technology)

ISO14443A Part 1 – 3 UID + Block

 Mifare 1k
 Mifare 4k
 Mifare UltraLight
 my-D proximity (SLE55Rxx)

ISO14443A+B Part 1 – 3 UID only

 my-C  SLE66CL160S

ISO15693 Part 1 – 3 UID only

 my-D vicinity (SRF55VxxP, SRF55VxxS)
 I-code SLI
 Tag-IT HFI
 LRI512 (STM)

▼
What is to be read ? Serial number

Data from block (direct)
Data from sector/block (direct)
Data from block via MAD (direct)

▼
Where are the data located ? Data in block x starting at y

Data in block z via MAD addressed with AID

▼
What is the data format ? Binary

BCD (4-bit, half byte)
ASCII (7-bit)
Wiegand format

▼
Which reader interface ? RS485

 CerPass reader protocol
 UCI reader protocol

Clock / Data

 Wiegand (D0, D1)
 5-bit ABA (clk, data, cls) - Magstripe Track II

▼
Data output format What is where in the output data string

Data format:

 5-bit ABA
 7-bit ASCII
 Wiegand

Without / with PIN

Detailed knowledge about the content to be read and the format, as well as a
possibly existing access protection, on the ID card is required.

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Transponders / ID cards

8.1 Qualified transponder types (ID cards)

8.1.1 ISO14443A Proximity read range

Type Manu-

facturer

UID UID

length
(byte)

Block Access block

Mifare Standard
1k (MF1 IC S50)

Philips ●

4

16-byte → 1 Mifare block after
authentication with KeyA or KeyB

Direct,
indirect (MAD)

Mifare Standard
4k (MF1 IC S70)

Philips ●

4

16-byte → 1 Mifare block after
authentication with KeyA or KeyB

Direct,
indirect (MAD)

SLE44R35S
(mifare)

Infineon ●

4

16-byte → 1 Mifare block after
authentication with KeyA or KeyB

Direct,
indirect (MAD)

SLE66R35
(mifare)

Infineon ●

4

16-byte → 1 Mifare block after
authentication with KeyA or KeyB

Direct,
indirect (MAD)

Mifare UltraLight
(MF0 IC U1)

Philips ●

7

16-byte → 4 consecutive pages at
4 bytes each

Direct

Mifare DESfire
(MF3 IC D40)

Philips ●

7 - -

my-D proximity
(SLE55Rxx)

Infineon ●

4

16-byte → 2 consecutive blocks at
8 bytes each in public mode

Direct

Note:
If UID is greater than 40 bits (5 bytes), the part to be analyzed has to be selected accordingly; see
configuration parameters C05, C06 in chapter 10.1 Config or ConfigCard parameters.

8.1.2 ISO14443A+B Proximity read range

Type Manu-

facturer

UID UID

length
(byte)

Block Access block

my-C
(SLE66CL160S)

Infineon ●

4 - -

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Transponders / ID cards

8.1.3 ISO15693 Vicinity read range

Type Manu-

facturer

UID UID

lengt
h
(byte)

Block Access block

my-D vicinity
(SRF55VxxP/S)

Infineon ●

8 - -

I-Code SLI Philips ●

8 - -

Tag-IT HFI Texas

Instruments

●

8 - -

LRI512 STMicro-

electronics

●

8 - -

Structure of the UID (ISO15693)

MSB LSB

64 57 56 49 48 . . . . . . . . . . . . . . . . . . . . . . . . . . 1

0xE0 MID SNR

SNR: 48-bit (6 bytes) "IC manufacturer serial number"
MID: 8-bit (1 byte) "IC manufacturer code" = Manufacturer code of the chip
manufacturer

0x07 Texas Instruments
0x05 Infineon
0x04 Philips
0x02 STMicroelectronics

0xE0: 8-bit (1 byte) fixed hex value

Note:
If UID is greater than 40 bits (5 bytes), the part to be analyzed has to be selected accordingly; see
configuration parameters C05, C06 in chapter 10.1 Config or ConfigCard parameters.

8.2 Information on transponder

The following information can be read from the transponder:

 Serial number (for more information please refer to chapter 8.2).
 Data from block (direct), e.g. ID number (for more information please refer to

chapter 8.2.2).

 Data from sector/block (direct), e.g. ID number (for more information please

refer to chapter 8.2.2).

 Data from sector via MAD (indirect), e.g. ID number (for more information

please refer to chapter 8.2.2).

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Transponders / ID cards

8.2.1 Serial number

The serial number is used as ID card number.

The serial number is a unique number of a transponder or a transponder
technology.

The length of the serial number differs depending on the transponder technology.
For more information please refer to chapter 8.1 Qualified transponder types (ID
cards).

The serial number stored in the transponder/ ID card is saved in binary format. The
card reader converts this binary value into a decimal value. The conversion from
binary to decimal is limited to max. 40 bits of the binary value. This means that
serial numbers longer than 40 bits are used only partially, preferably the low-order
40 bits.

A test selection of the higher-order bits can be performed in the card reader. This
test selection helps to avoid the detection of two or several different cards with the
same 40-bit long serial number. Test selection and analysis of the higher-order bits
of a serial number can be performed using UID_MASK and UID_PATTERN (for
more information please refer to chapter 10 under C05

and C06).

The following parameters are required when using the serial number:

UID_OUT

With UID_START (higher-order half byte) and
UID_LNG (lower-order half byte),
start byte at which the serial number is used and
number of bytes of the serial number (max. 5 bytes -> 40-bit)

UID_OUT 

0x05 Use start at byte 0 and 5 byte;
40 lowest-order bits of the serial number
(e.g. Mifare UltraLight)
0x04 Use start at byte 0 and 5 byte;
32 lowest-order bits of the serial number (e.g. Mifare)

8.2.2 ID number

The ID number is an identification number written to the memory area of the ID
card (= transponders). For this purpose, the writing of an ID number is considered
as personalizing. The ID number can be freely defined and has to be based on the
same system-wide rules.

These rules are in general:

 Uniqueness within a system
 Standardized structure
 Standardized set of values, e.g. only numerical values
 Standardized data format; e.g. BCD format (4-bit)

The memory area on the card is defined as a block in the available EEProm
memory of the respective transponder technology. Depending on the transponder
type used, access to the data is via "public mode" (direct addressing of memory
block without access protection) or "safe mode" (direct addressing of memory block
with access protection authentication).

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Transponders / ID cards

The block to be read can be addressed directly (e.g. by block number) or indirectly
to the memory block of the transponder (e.g. in case of Mifare
MifareApplicationDirectory).

Access to a block with written data is to be set with the different configuration
parameters of the card reader AR6181-MX.

Parameters to access a personalized block:

 Block address (for more information please refer to chapter 10 under

SL_BLOCK

).

 Access protection (see above)
 Start and end of ID number in block (for more information please refer to

chapter 8.3).

 Format of ID number (for more information please refer to chapter 8.3).

Details about the respective parameters are listed in the individual chapters.

8.3 Data formats of the Transponder

The following data formats of the transponder can be used:

Serial number: Binary, max. 40 bits (5-byte)

ID number: BCD (4-bit) format
ASCII (7-bit) format
Wiegand format

8.3.1 BCD format

The BCD format consists of numerical values 0-9 and uses a half byte each
(4-bit). Two values each are saved in one byte of the ID card.

The data stored on the ID card are max. 32 characters long:

00 01 23 45 67 89 00 00 00 00 00 00 00 00 00 00 (Hex)

The length is defined with the parameters ID_START and ID_LEN. For more
information please refer to chapter 10 under ID_START

and ID_LEN.

The transfer is carried out per numerical value (in ABA format).

Example:

10 10 10 01 02 13 04 15 16 07 08 19 10 10 10 10 10 . . . . 10 10 10

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Transponders / ID cards

8.3.2 ASCII format

The ASCII format consists of alphanumerical values as defined in the ASCII
(7-bit) table/rule. Depending on the output protocol, the individual characters can
be transferred in two parts as a half byte.

Configuration "UCI-CODING" = 0 ⇒ ASCII (default)

The data stored on the ID card are max. 16 bytes (ASCII):

"1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6" (ASCII)
31 32 33 34 35 36 37 38 39 30 31 32 33 34 36 (Hex)

The length is defined with the parameters ID_START and ID_LEN. For more
information please refer to chapter 10 under ID_START

and ID_LEN.

Data are transferred as:

"1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6" (ASCII)
31 32 33 34 35 36 37 38 39 30 31 32 33 34 36 (Hex)

Configuration "UCI-CODING" = 1 ⇒ SIPASS Format

The data stored on the ID card are max. 16 bytes (ASCII):

x x x x A P D 1 2 3 4 5 6 x x V

x: Not relevant
APD: APD number
1 . . 6: ID card number
V: Version number

Data are transferred as:

0 0 S 0 0 0 0 0

A P D 1 2 3 4 5 6 V 0 0 0

Underlined values are fixed values added by readers (S – 53

hex

).

8.3.3 Wiegand format

The Wiegand format is a bit-based format where individual blocks are assigned to
certain functions (e.g. facility code, ID number). The content of a block consists of
binary values with defined bit length. For output, the Wiegand format is transferred
1:1 (Wiegand interface) or is interpretatively prepared and the binary
values/contents are transferred as decimal equivalents.

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Card reader configuration

9 Card reader configuration

The configuration of the card reader is performed with the ConfigCard or the serial
RS485 interface and a terminal program. For more information please refer to
chapter 9.2 Launching the terminal program. The ConfigCard is a proximity ID card
(Mifare) which is written with the help of the ConfigCard Creation Tool (optional
software) and the parameters. The parameters from the ConfigCard can be read
from the AR618x-MX after a power-up.

Requirement

To run the terminal program with AR618x-MX you have to connect the reader to
your PC. Use serial communication line COM1/2, a converter RS485/232 and a
connecting cable.

24

RS485/RS232

AR6181-MX

9 V power

adapte

r

12 V-

power

adapter

Power supply

A

B

Wall power supply plug

Mains power supply
Terminal 1 + 12 V
Terminal 2 GND

R

/A

T/B

RS232

1:1 cable

COM1

PC

The special configuration mode can be reached with the following DIP settings. In
this position no cards will be read or any card information transmitted.

DIP 1, DIP 2, DIP 3, DIP 4 = off or on

DIP 5, DIP 6 = on

DIP 7, DIP 8 = off or on

Within configuration mode you may check or change some additional settings or
get information out of the reader with a terminal program, e.g. HyperTerminal. For
more information please refer to chapters 9.2 and 9.3.

Siemens Building Technologies
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Card reader configuration

9.1 Defining parameters

Use an editor such as Notepad, for example, to define the Config or ConfigCard
parameters.

For more information about defining the configuration parameters C00-C06 please
refer to chapter 10.1 Config or ConfigCard parameters.

For more information about defining the reader keys Kxx please refer to
chapter 10.4 Defining reading keys with Mifare Standard 1k and 4k.

9.2 Launching the terminal program

The program "HyperTerminal" is a component of the Windows operating system.

Use the configuration mode and "HyperTerminal" to exchange data with the reader
AR618x-MX.

In order to be able to use "HyperTerminal" in the configuration mode, the following
settings, depicted below, are required.

1. Launch the terminal program via the Windows Start menu and then select

Programs-> Accessories-> Communication ->HyperTerminal.

 When started successfully this dialog box opens:

Enter a name such as Config_AR618x-MX into the name field.

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Card reader configuration

2. Confirm by clicking on OK.

Select the COM port.

3. Confirm by clicking on OK.

Now select the following parameters:

Bits per second 9600
Data bits 8
Parity None
Stop bits 1
Flow control None

4. Confirm by clicking on OK.
"HyperTerminal" has been started successfully.

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Card reader configuration

9.3 Configuration mode of the Terminal program

1. Start the program "HyperTerminal." Please see chapter 9.2 Launching the
terminal program.

2. Select "Properties" from the "File" menu.

 The following dialog box opens:

Select the following parameters on the "Settings" tab:

3. Click on

.

 The following dialog box opens:

Specify the following parameters in the dialog box:

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Card reader configuration

4. Select "Send File" from the "Transfer" menu.

 The following dialog box opens:

Select the desired file, which you have edited.
(Please see chapter 9.1 Defining parameters).

5. Click on the Open button.

 The following dialog box opens:

The data were then successfully loaded.

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Card reader configuration

9.3.1 Commands

The following functions are possible by entering the following commands (in capital
letters):

UPLOAD

to read all configuration parameter sets

DOWNLOAD

to write new parameter sets

RSTDEF

reset reader to default parameter values.
The default parameters can be found in chapter 10.

FIRMWARE

to load new firmware into your reader. More information
can be found in chapter 9.3.1.1.

Example:

"UPLOAD" command to read the configuration parameters from the card reader.

9.3.1.1 Firmware, new load

 Prerequisite: DIP switches 5 and 6 must be in ON position.

1. Start the program “HyperTerminal”. See also chapter 9.2 Launching the
terminal program

2. Enter the command „FIRMWARE“.

 The message START BOOTLOADER is displayed (see figure)

3. Select „New Connection“ from the „File“ menu.

 The following dialog box opens:

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Card reader configuration

Enter a name such as UPDATE into the name field and confirm by clicking on
OK.

4. Select the COM port and confirm by clicking on OK.

 The following dialog box opens:

Now select the following parameters:

Bits per second 38400
Data bits 8
Parity None
Stop bits 1
Flow control None

5. Confirm by clicking on OK.

6. After pressing the Return key the following message is displayed:

7. Enter the command „FLASHALL“.

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Card reader configuration

Note:
When this command has been sent the reader must not be disconnected from the power supply.

 This is acknowledged with the message "ERASE WAIT"
 You are now prompted to send the firmware mhx file: "START DOWNLOAD".

You have about 2 minutes to do this.
During this period, the characters "C" and "§" will appear at intervals of

5 seconds. If no mhx file is sent within these 2 minutes, the message
"ERROR 1" will appear and the command "FLASHALL" will have to be
entered once more. Do not disconnect the reader!

8. Select „Send File“ from the „Transfer“ menu.

 The following dialog box opens:

Enter the desired file into the filename field and Xmodem into the Protocol
field.

9. Click on „Send“ to send the file.

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Card reader configuration

9.4 Reader interface

The card readers AR6181-MX and AR6182-MX have to be connected via a RS485
bus interface, 2-wire, to the reader interface of the interface unit (e.g. DRI) or a
door controller. For that a 4-wire, twisted pair, shielded cable is required. One pair
is for the 2-wire RS485 party line and the other pair for power supply of the reader.
The maximum allowed bus length is 1200 m (at 9600 Baud).

The card readers AR618x-MX do have an Clock/Data interface which fulfils either
the Omron (ABA format) / Magstripe Track II or the Wiegand interface
requirements.

More information on Address setting for RS485 bus operation, 2-wire, can be found
in chapter 7.1 and on Setting the address (Clock/Data) in chapter 7.2.

The output of the read card information is transferred to the parent system (reader
interface, door controller) by means of the different interfaces of the reader.
Depending on the interface used, certain transfer formats and data formats have to
be applied. For more information please refer to chapter 10.2 Combination options.

Available interfaces (see chapter 6)

RS485:

CerPass reader protocol (Data format: ASCII)
UCI reader protocol

(Data format: BCD, ASCII)

Clock/Data:

Omron (Data format: ABA coded (5-bit)

Wiegand (Wiegand format / Data 1 : 1)

9.5 Output data formats

The output data formats that are possible are defined by the interface used and the
associated protocol.

The data formats for the RS485 interfaces are in BCD or ASCII format depending
on the reader protocol used.

The data formats of the clock/data interface depend on the interface and the
technology used with the interface.

Omron/Magstripe Track II:

Transfers BCD data formats in ABA format (4 bits +
parity 1 bit) with the corresponding additional
control characters in the protocol.

Wiegand:

Transfers bit data with additional parity bits based
on the respective Wiegand format definitions (e.g.
26 and 37 bits).

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Configuration parameters

10 Configuration parameters

10.1 Config or ConfigCard parameters

0 1 2 3 4 5 6 7 8 9 10 11 12 13

CARD_TEC

CONFIG

_CARD

C00

General 1

0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x07 0x00 0x00 0x00 0x00

UCI_

Coding

TAG-

BEEP

TAG-

LED

PIN_

MODE

PIN_

BUF

ID_

START

ID_

LEN

C01

General 2

0x00 0x00 0x00 0x02 0x00 0x00 0x00 0x00 0x20 0x00 0x00 0x00 0x00 0x00
WG_

Coding

WG_

CD_ss

WG_

CD_ee

WG_

CC_ss

WG_

CC_ee

WG_

CC_nn

WG_

FC_ss

WG_

FC_ee

WG_

FC_nn

WG_

CN_ss

WG_

CN_ee

WG_

CN_nn

C02

Wiegand

0x00 0x00 0x00 0x01 0x1A 0x00 0x00 0x00 0x02 0x09 0x03 0x0A 0x19 0x05
WG_

EV_ss

WG_

EV_ee

WG_

EV_pp

WG_

OD_ss

WG_

OD_ee

WG_

OD_pp

C03

Wiegand

0x02 0x0D 0x01 0x0E 0x19 0x1A 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00
A_ID

SL_

BLOCK

MF_KEY

_TYPE

MF_KEY

_NO

MF_

BLOCK

MF_

MAD

MF_

AID1

MF_

AID0

MF_UL_

BLOCK

C04

Others

0x07 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00

(MSB) UID_MASK (LSB)

UID

_OUT

C05

UID Mask

0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x05 0x00 0x00 0x00

UID_PATTERN

C06
UID
Patter
n

0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00

Listed values are default values (factory settings of the reader
AR618x-MX)

C00

CARD_TEC Card technology, defines which transponder types or standards are processed by the reader.

A Drivers for transponders acc. to ISO/IEC 14443-A
0: Deactivates drivers for transponders acc. to ISO/IEC 14443-A
1: Activates drivers for transponders acc. to ISO/IEC 14443-A
B Drivers for transponders acc. to ISO/IEC 14443-B
0: Deactivates drivers for transponders acc. to ISO/IEC 14443-B
1 Activates drivers for transponders acc. to ISO/IEC 14443-B
C Drivers for transponders acc. to ISO/IEC 15693
0 Deactivates drivers for transponders acc. to ISO/IEC 15693
1 Activates drivers for transponders acc. to ISO/IEC 15693
0x0000 No transponder
0x0001 ISO14443-A transponder only
0x0002 ISO14443-B transponder only
0x0003 ISO14443-A+B transponder
0x0004 ISO15693 transponder only
0x0005 ISO14443-A + 15693 transponder
0x0006 ISO14443-B + 15693 transponder
0x0007 ISO14443-A+B + 15693 transponder

CONFIG_CARD 0x00 After a power on reset, the configuration mode is active for 5 seconds.

0x01 The configuration mode is active during normal operation if driver A has been activated.

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Configuration parameters

C01

UCI_Coding UCI reader protocol, UID and ID number

0x00 CSN: ABA code, ID No.: ASCII code
0x01 CSN: SIPASS code, ID No.: SIPASS card format

TAG_BEEP 0x00 No acoustic signal with detected transponder

0x02 … 0xFF x number of timer ticks per 10ms

TAG_LED 0x00 No LED off flash

0x02 … 0xFF x 10 ms switch off LED

PIN_MODE 0x00 PIN before card

 Enter PIN and confirm with <E>; the entered PIN is transferred
 PIN is entered, but not confirmed with <E>; a card has to be read within 10 sec In this case,

the card works analog to the <E> key

0x01 ID mode:

 Enter PIN and confirm with <E>; PIN is aligned left and transferred in the UCI protocol

instead of the card data
Input: 1,2,3,4 E Output: 1 2 3 4 0 0 0 0 0 0 0 0 0 0 0

0x02 Card before PIN

After a card has been read, a PIN can be entered within the started waiting time of 10 sec.
Transfer with E key or when number PIN digits has been reached. If no PIN is entered but <E>
is used to confirm, only the card data are sent.

0x03 Special mode:

Keys <E> and <C> are special cases.
First <E>, then card or PIN, then <E>, then card
The letter "B" (0x42) is then listed in the transaction telegram after the PIN

First <C>, then card or PIN, then <C>, then card
The letter "A" (0x41) is then listed in the transaction telegram after the PIN

PIN_BUF

Definition of the max. number of PIN digits
Note: In PIN:MODE 0x03 the keys are not part of the PIN.

0x00

Default buffer length, depending on interface:

Configuration

PIN digits

RS485, UCI reader protocol

7

RS485, CerPass reader protocol

6

Clock/Data, Wiegand

8

Clock/Data, Omron

8

0x01 … 0x08 Parameters to change number of PIN digits

ID_START 0x00 ... 0x1F First data nibble to be transferred from the ID number (with ASCII data, the values have to be

divisible by 2)

ID_LEN 0x01 ... 0x20 Number of data nibbles to be transferred (with ASCII data, the values have to be divisible by 2)

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Configuration parameters

C02 and C03

Wiegand format, data on ID card (ID number in Wiegand format)

Wiegand-formatted data in conjunction with UCI reader protocol:

WG_CODING 0x00 BCD-coded (4-bit) in reader protocol

0x01 ASCII-coded (7-bit) in reader protocol

When transferring via Wiegand interface:

WG_CD_ss

0x01 . . . 0x80

Start bit digit Wiegand format data 0x00: Funktion disabled

WG_CD_ss

0x01 . . . 0x80

End bit digit Wiegand format data 0x00: Funktion disabled

When transferring via RS485 and Omron interface:

WG_CC_ss

0x01 . . . 0x80

Start bit digit company code 0x00: Funktion disabled

WG_CC_ee

0x01 . . . 0x80

End bit digit company code 0x00: Funktion disabled

WG_CC_nn

0x01 . . . 0x10

Number of BCD digits for conversion, incl. leading zeros

WG_FC_ss

0x01 . . . 0x80

Start bit digit facility code 0x00: Funktion disabled

WG_FC_ee

0x01 . . . 0x80

End bit digit facility code 0x00: Funktion disabled

WG_FC_nn

0x01 . . . 0x10

Number of BCD digits for conversion, incl. leading zeros

WG_CN_ss

0x01 . . . 0x80

Start bit digit card number 0x00: Funktion disabled

WG_CN_ee

0x01 . . . 0x80

End bit digit card number 0x00: Funktion disabled

WG_CN_nn

0x01 . . . 0x10

Number of BCD digits for conversion, incl. leading zeros

WG_EV_ss

0x01 . . . 0x80

Start bit digit for even parity bit generation 0x00: Funktion disabled

WG_EV_ee

0x01 . . . 0x80

End bit digit for even parity bit generation 0x00: Funktion disabled

WG_EV_pp

0x01 . . . 0x80

Bit position of even parity bit

WG_OD_ss

0x01 . . . 0x80

Start bit digit for odd parity bit generation

WG_OD_ee

0x01 . . . 0x80

End bit digit for odd parity bit generation

WG_OD_pp

0x01 . . . 0x80

Bit position of odd parity bit

Notes:

 The difference between "ee" and "ss" of a Wiegand format code may not exceed 40 bits.
 The total number of BCD digits ("nn" parameter) may not exceed 16 digits (64 bits).
 When data is output, the BCD value is right-aligned and leading digits are filled with = (0x30) until

"nn" digits have been reached

 If the BCD value exceeds the value range defined by "nn" the higher-order digits are truncated
 Data are transferred in the following order:

CompanyCode (CC), FacilityCode (FC), CardNumber (CN)

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Configuration parameters

C04

A_ID

Access to ID memory (only Mifare 1k and 4k, Mifare UltraLight, my-D proximity)
Parameter to activate / deactivate the function for the data block or ID. Reading from the
listed transponder types:

Bit:

7 6 5 4 3 2 1 0

Function

0 0 0 0

UL SL MF

MF: Mifare Standard (1k and 4k)
0: ID reading disabled
1: ID reading enabled

SL: my-d proximity SLE55R (04 …16)
0: ID reading disabled
1: ID reading enabled

UL: Mifare UltraLight
0: ID reading disabled

1: ID reading enabled
0x00 ID reading disabled
0x01 ID reading from Mifare Standard (1k + 4k)
0x02 ID reading from my-D proximity (SLE55R04 … 16)
0x03 ID reading from Mifare Standard and my-D proximity
0x04 ID reading from Mifare UltraLight
0x05 ID reading from Mifare Standard and Mifare UltraLight
0x06 ID reading from Mifare UltraLight and my-D proximity
0x07 ID reading from Mifare Standard / Ultralight and my-D proximity

SL_BLOCK Definition of the first page to be read from an Infineon my-d (e.g. SLE55...). Incl. SL_BLOCK, 2 consecutive

blocks (16-byte) are read. The useable pages of the transponder are numbered consecutively.
0x00 … 0x40 ... 0xFF my-D proximity block address

MF_UL_BLOCK 0x04 ... 0x0F Page address in Mifare UltraLight
Mifare Ultralight page address. Definition of the first page to be read by the reader. Incl. MF_UL_BLOCK , 4

consecutive blocks (16-byte) are read. The useable pages of the transponder are numbered consecutively.

Direct access to Mifare Standard
MF_KEY_TYPE 0x00 Defining KeyA for reading

0x01 Defining KeyB for reading

MF_KEY_NO 0x00 ... 0x1F Reading key (key number), used to read a Mifare sector
MF_BLOCK 0x00 ... 0xFF Mifare Standard block address (block 3 of a sector, safety block, is not counted)

Indirect access via MAD in Mifare Standard
MF_KEY_TYPE 0x00 Defining KeyA for reading

0x01 Defining KeyB for reading

MF_KEY_NO 0x00 … 0x1F Reading key (key number), used to read a Mifare sector
MF_BLOCK 0x00 ... 0x03… 0x15 Block address within a sector that is addressed via MAD: Mifare 1k (0x03) and Mifare 4k

(0x03 – first two 1k ranges – and 0x15 – last two 1 k ranges)

MF_MAD 0x00 Deactivates MAD

0x01 MAD is to be used (MAD1 in sector 0, MAD2 in sector 16, only with Mifare 4k)

MF_AID1 / MF_AID0

AID of the application, for search in MAD

(AID1 – higher-order byte, AID0 – lower-order byte)
0x00 ... 0x03 When using MAD, block in sector Mifare 1k
0x00 … 0x15 When using MAD, block in sector Mifare 4k

C05 and C06

Selecting the UID of a transponder

UID_OUT

UID_Start
(left half byte)

Starting byte position where the UID transfer starts (0x0 . . . 0x9)

UID_LNG
(right half byte)

Number of bytes of the UID to be transferred (0x1 . . 0x5)

With a UID that is larger than 40 bits, the qualified transponders can be limited by

masking the higher-order digits accordingly and qualifying them using a selective test

pattern.

UID_MASK

Masking the bit digits of the UID to be checked (80-bit)

UID_Pattern

Test pattern for UID (matching of the masked UID parts) (80-bit)

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Configuration parameters

10.2 Combination options

10.2.1 Serial number RS485 – CerPass reader protocol

The unique serial number is transferred as a decimal equivalent.

DIP switch DIP1 . . DIP4 = reader address, DIP5 = 0, DIP6 = 1, DIP7/DIP8 = 0

Parameter:
Transponder: UID_OUT with UID_START, UID_LNG

UID_MASK, UID_PATTERN

PIN: PIN_MODE, PIN_BUF (default = 6)
General: CARD_TEC, TAG_BEEP, TAG_LED, CONFIG_CARD

Transferred:
ID card data: 16 characters in ASCII format of which 13 are ID card number characters,

aligned left, filled with zeros (0x30) – (telegram identifier: Kg)

PIN: see Setting  PIN input CerPass reader protocol in chapter 10.3.1.

10.2.2 Serial number RS485 – UCI reader protocol

The unique serial number is transferred as a decimal equivalent.

DIP switch DIP1 . . DIP4 = reader address, DIP5 = 0, DIP6 = 0, DIP7/DIP8 = 0

Parameter:
Transponder: UID_OUT with UID_START, UID_LNG

UID_MASK, UID_PATTERN

Output format: UCI-CODING (default = 0
PIN: PIN_MODE, PIN_BUF (default = 7)
General: CARD_TEC, TAG_BEEP, TAG_LED, CONFIG_CARD

Transferred:

ID card data:
UCI_CODING = 0 Card number in BCD / ABA format, 13 digits, aligned right, with leading zeros

With PIN code: No separator between data and PIN.

UCI-CODING =1 Card number in ASCII / SIPASS format, 13 digits, aligned right, with leading

zeros
With PIN code: Separator between data and PIN.

PIN:

see Setting  PIN input UCI reader protocol in chapter 10.3.2.

10.2.3 Serial number Clock / Data – Omron interface

The unique serial number is transferred as a decimal equivalent.

DIP switch DIP1 . . DIP3 = off, DIP4 = 1, DIP5 = 1, DIP6 = 0, DIP7/DIP8 = 0

Parameter:
Transponder: UID_OUT with UID_START, UID_LNG

UID_MASK, UID_PATTERN

PIN: No parameters (PIN length is = 8, fixed)
General: CARD_TEC, TAG_BEEP, TAG_LED, CONFIG_CARD

Transferred:
ID card data: Card number in ABA format (5-bit), 13 digits, aligned right, filled with zeros
PIN: see Setting  PIN input Clock / Data - Omron Interface in chapter 10.3.3.

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Configuration parameters

10.2.4 Serial number Clock / Data – Wiegand interface

The unique serial number is transferred as a decimal equivalent.

DIP switch DIP1 . . DIP3 = off, DIP4 = 0, DIP5 = 1, DIP6 = 0, DIP7/DIP8 = 0

Parameter:
Transponder: UID_OUT with UID_START, UID_LNG

UID_MASK, UID_PATTERN

PIN: No parameters (PIN length is = 8, fixed)
General: CARD_TEC, TAG_BEEP, TAG_LED, CONFIG_CARD

Transferred:
ID card data: Card number in BCD format (4-bit), 13 digits, aligned right, filled with zeros

Output via Wiegand interface; not a Wiegand-conforming data format!

PIN: see Setting  PIN input Clock / Data - Wiegand Interface in chapter 10.3.4.

10.2.5 ID number – ASCII format RS485 – CerPass reader protocol

The ID number / card number personalized in ASCII format is transferred.

DIP switch DIP1 . . DIP4 = reader address, DIP5 = 0, DIP6 = 1, DIP7 = 1, DIP8 = 0

Parameter:
Transponder: ID_START, ID_LEN

Direct: MF_BLOCK or MF_UL_Block or SL_BLOCK
Indirect: MF_MAD, MF_AID1, MF_AID0 (Mifare – MAD)
MF_BLOCK

PIN: PIN_MODE, PIN_BUF (default = 6)
General: CARD_TEC, TAG_BEEP, TAG_LED, CONFIG_CARD, A_ID

MF_BLOCK, MF_KEY_TYPE, MF_KEY_NO Mifare Standard
MF_UL_BLOCK Mifare UltraLight
SL_BLOCK my-D proximity

Transferred:
ID card data: 16 characters in ASCII format of which 13 are ID card number characters,

aligned left, filled with zeros (0x30) – (telegram identifier: Kg)

PIN: see Setting  PIN input CerPass Reader Protocol in chapter 10.3.1.

10.2.6 ID number – ASCII format RS485 – UCI reader protocol

The ID number / card number personalized in ASCII format is transferred.

DIP switch DIP1 . . DIP4 = reader address, DIP5/DIP6 = 0, DIP7 = 1, DIP8 = 1

Parameter:
Transponder: ID_START, ID_LEN

Direct: MF_BLOCK or MF_UL_Block or SL_BLOCK
Indirect: MF_MAD, MF_AID1, MF_AID0 (Mifare – MAD), MF_BLOCK

Interface: UCI_CODING (default = 0)
PIN: PIN_MODE, PIN_BUF (default = 7)
General: CARD_TEC, TAG_BEEP, TAG_LED, CONFIG_CARD, A_ID

MF_BLOCK, MF_KEY_TYPE, MF_KEY_NO Mifare Standard
MF_UL_BLOCK Mifare UltraLight
SL_BLOCK my-D proximity

Transferred:
ID card data: 16 characters in ASCII format of which 13 are ID card number characters,

aligned left, filled with zeros (0x30)

PIN: see Setting  PIN input UCI Reader Protocol in chapter 10.3.2.

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Configuration parameters

10.2.7 ID number – BCD format RS485 – CerPass reader protocol

The ID number / card number personalized in BCD format is transferred.

DIP switch DIP1 . . DIP4 = reader address, DIP5 = 0, DIP6 = 1, DIP7 = 1, DIP8 = 1

Parameter:
Transponder: ID_START, ID_LEN

Direct: MF_BLOCK or MF_UL_Block or SL_BLOCK
Indirect: MF_MAD, MF_AID1, MF_AID0 (Mifare – MAD), MF_BLOCK

PIN: PIN_MODE, PIN_BUF (default = 6)
General: CARD_TEC, TAG_BEEP, TAG_LED, CONFIG_CARD, A_ID

MF_BLOCK, MF_KEY_TYPE, MF_KEY_NO Mifare Standard
MF_UL_BLOCK Mifare UltraLight
SL_BLOCK my-D proximity

Transferred:
ID card data: 16 characters in BCD format of which 13 are ID card number characters,

aligned left, filled with zeros (0x30)

PIN: see Setting  PIN input CerPass Reader Protocol in chapter 10.3.2.

10.2.8 ID number – BCD format RS485 – UCI reader protocol

The ID number / card number personalized in BCD format is transferred.

DIP switch DIP1 . . DIP4 = reader address, DIP5/DIP6 = 0, DIP7 = 1, DIP8 = 0

Parameter:
Transponder: ID_START, ID_LEN

Direct: MF_BLOCK or MF_UL_Block or SL_BLOCK
Indirect: MF_MAD, MF_AID1, MF_AID0 (Mifare – MAD), MF_BLOCK

PIN: PIN_MODE, PIN_BUF (default = 7)
General: CARD_TEC, TAG_BEEP, TAG_LED, CONFIG_CARD, A_ID

MF_BLOCK, MF_KEY_TYPE, MF_KEY_NO Mifare Standard
MF_UL_BLOCK Mifare UltraLight
SL_BLOCK my-D proximity

Transferred:
ID card data: 16 characters in ASCII format of which 13 are ID card number characters,

aligned left, filled with zeros (0x30)

PIN: see Setting  PIN input UCI Reader Protocol in chapter 10.3.2.

10.2.9 ID number – BCD/ASCII format Clock / Data: Omron interface

The ID number / card number personalized in BCD or ASCII format is transferred.

DIP switch DIP1 . . DIP3 = off, DIP4 = 1, DIP5 = 1, DIP6 = 0, DIP7 = 1 DIP8 = 0

Parameter:
Transponder: ID_START, ID_LEN

Direct: MF_BLOCK or MF_UL_Block or SL_BLOCK
Indirect: MF_MAD, MF_AID1, MF_AID0 (Mifare – MAD), MF_BLOCK

Interface: UCI_CODING (default = 0)
PIN: PIN_MODE, PIN_BUF (default = 6)
General: General: CARD_TEC, TAG_BEEP, TAG_LED, CONFIG_CARD, A_ID

MF_BLOCK, MF_KEY_TYPE, MF_KEY_NO Mifare standard
MF_UL_BLOCK Mifare UltraLight
SL_BLOCK my-D proximity

Transferred:
ID card data: 16 characters in ASCII format of which 13 are ID card number characters,

aligned left, filled with zeros (0x30) – (telegram identifier: Kg)

PIN: see Setting  PIN input Clock / Data - Omron Interface in chapter 10.3.3.

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Configuration parameters

10.2.10 ID number – Wiegand format RS485 – CerPass reader protocol

The ID number / card number personalized in Wiegand format is transferred.

DIP switch DIP1 . . DIP4 = reader address, DIP5 = 0, DIP6 = 1, DIP7 = 0, DIP8 = 1

Parameter:
Transponder: WG_CC_ss, WG_CC_ee, WG_CC_nn

WG_FC_ss, WG_FC_ee, WG_FC_nn
WG_CN_ss, WG_CN_ee, WG_CN_nn
WG_EV_ss, WG_EV_ee, WG_EV_pp
WG_OD_ss, WG_OD_ee, WG_OD_pp

Direct: MF_BLOCK or MF_UL_Block or SL_BLOCK
Indirect: MF_MAD, MF_AID1, MF_AID0 (Mifare – MAD), MF_BLOCK

PIN: PIN_MODE, PIN_BUF (default = 6)
General: CARD_TEC, TAG_BEEP, TAG_LED, CONFIG_CARD, A_ID

MF_BLOCK, MF_KEY_TYPE, MF_KEY_NO Mifare Standard
MF_UL_BLOCK Mifare UltraLight
SL_BLOCK my-D proximity

Transferred:
ID card data: ID number in Wiegand format is interpreted in accordance with the

WG_xx_ss and WG_xx_ee configuration parameters, converted to a decimal
value, and sent as ASCII values; any possibly required leading zeros are to be
considered during parameterization (WG_xx_nn parameter), (telegram
identifier: Kg)

PIN: see Setting  PIN input CerPass Reader Protocol in chapter 10.3.1.

10.2.11 ID number – Wiegand format RS485 – UCI reader protocol

The ID number / card number personalized in Wiegand format is transferred.

DIP switch DIP1 . . DIP4 = reader address, DIP5/DIP6 = 0, DIP7 = 1, DIP8 = 0

Parameter:
Transponder: WG_CC_ss, WG_CC_ee, WG_CC_nn

WG_FC_ss, WG_FC_ee, WG_FC_nn
WG_CN_ss, WG_CN_ee, WG_CN_nn
WG_EV_ss, WG_EV_ee, WG_EV_pp
WG_OD_ss, WG_OD_ee, WG_OD_pp
WG_CODING (default = 0)
Direct: MF_BLOCK or MF_UL_Block or SL_BLOCK
Indirect: MF_MAD, MF_AID1, MF_AID0 (Mifare – MAD), MF_BLOCK

Interface: None
PIN: PIN_MODE, PIN_BUF (default = 7)
General: CARD_TEC, TAG_BEEP, TAG_LED, CONFIG_CARD, A_ID

MF_BLOCK, MF_KEY_TYPE, MF_KEY_NO Mifare Standard
MF_UL_BLOCK Mifare UltraLight
SL_BLOCK my-D proximity

Transferred:
ID card data: ID number in Wiegand format is interpreted in accordance with the

WG_xx_ss and WG_xx_ee configuration parameters, converted to a decimal
value, and sent as BCD or ASCII values; any possibly required leading zeros
are to be considered during parameterization (WG_xx_nn parameter)

PIN: see Setting  PIN input UCI Reader Protocol in chapter 10.3.2.

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Configuration parameters

10.2.12 ID number – Wiegand format Clock/Data: Wiegand interface

The ID number / card number personalized in Wiegand format is transferred.

DIP switch DIP1 . . DIP3 = off, DIP4 = 0, DIP5 = 1, DIP6 = 0, DIP7 = 0, DIP8 = 1

Parameter:
Transponder: WG_CD_ss, WG_CD_ee

Direct: MF_BLOCK or MF_UL_Block or SL_BLOCK
Indirect: MF_MAD, MF_AID1, MF_AID0 (Mifare – MAD)

PIN: PIN_MODE, PIN_BUF (default = 6)
General: CARD_TEC, TAG_BEEP, TAG_LED, CONFIG_CARD, A_ID

MF_BLOCK, MF_KEY_TYPE, MF_KEY_NO Mifare Standard
MF_UL_BLOCK Mifare UltraLight
SL_BLOCK my-D proximity

Transferred:
ID card data: The ID number / card number in Wiegand format is output via the Wiegand

interface bit by bit

PIN: see Setting  PIN input Clock / Data - Wiegand Interface in chapter 10.3.4.

10.2.13 ID number – Wiegand format Clock/Data: Omron interface

The ID number / card number personalized in Wiegand format is transferred.

DIP switch DIP1 . . DIP3 = off, DIP4 = 1, DIP5 = 1, DIP6 = 0, DIP7 = 0, DIP8 = 1

Parameter:
Transponder: WG_CC_ss, WG_CC_ee, WG_CC_nn

WG_FC_ss, WG_FC_ee, WG_FC_nn
WG_CN_ss, WG_CN_ee, WG_CN_nn
WG_EV_ss, WG_EV_ee, WG_EV_pp
WG_OD_ss, WG_OD_ee, WG_OD_pp

Direct: MF_BLOCK or MF_UL_Block or SL_BLOCK
Indirect: MF_MAD, MF_AID1, MF_AID0 (Mifare – MAD), MF_BLOCK

PIN: PIN_MODE, PIN_BUF (default = 6)
General: CARD_TEC, TAG_BEEP, TAG_LED, CONFIG_CARD, A_ID

MF_BLOCK, MF_KEY_TYPE, MF_KEY_NO Mifare Standard
MF_UL_BLOCK Mifare UltraLight
SL_BLOCK my-D proximity

Transferred:
ID card data: ID number in Wiegand format is interpreted in accordance with the

WG_xx_ss and WG_xx_ee configuration parameters, converted to a decimal
value, and sent as BCD values in ABA format (5-bit); any possibly required
leading zeros are to be considered during parameterization (WG_xx_nn
parameter)

PIN: see Setting  PIN input Clock / Data - Omron Interface in chapter 10.3.3.

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Configuration parameters

10.3 PIN code

The PIN can be entered before or after the ID card booking, depending on the
setting.

The basic rule is that the max. waiting time between input and ID card booking is
10 seconds. Once this delay has expired, the input is cancelled and the entire
process is discarded, i.e. the input of transponder / ID card has to be repeated.

PIN input can be cancelled with the C key. This means the entire process has to be
repeated.

Using the E key completes the PIN input process and the entered PIN is then
processed based on the set parameters.

If the PIN is input before the transponder, the E key completes the input process
and the PIN data are sent.

If the PIN input is completed with a transponder, the ID card number is transferred
together with the entered PIN.

Further details about PIN handling, insofar as the process differs from the one
described here, are described below with the individual settings.

10.3.1 RS485 – CerPass reader protocol

PIN_MODE 0x00 PIN before transponder

PIN input and completion with E key  PIN code as ID card number
(telegr. identifier: Kg)

PIN input and transponder within 10 seconds  ID card number with PIN code
(telegr. identifier: Hk)

0x02 Transponder before PIN

Transponder, LED flashes green and waits 10 seconds for key input
No PIN input: Discard and cancellation
Only E key:  ID card number (telegr. identifier: Kg)
PIN input:  ID card number with PIN code (telegr. identifier: Hk)
PIN before transponder
PIN input with PIN input  as with PIN_MODE = 0x00
PIN input with E key  same as with PIN_MODE = 0x00

0x01 or 0x03 Not permissible

PIN_BUF 0x00 Use of default buffer length, depending on the interface. For more information please refer to

C01

, PIN_BUF in chapter 8.

0x01 ... 0x06 Number of permissible PIN digits, autom. completion if number of digits reached; otherwise

finish with E key!

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Configuration parameters

10.3.2 RS485 – UCI reader protocol

PIN_MODE 0x00 PIN before transponder

PIN input and completion with E key  PIN code is transferred alone, ID card number is 0
PIN input and transponder within 10 seconds  ID card number with PIN code

0x01 ID mode

PIN code and completion with E key  PIN code is transferred as ID card number, aligned
right, leading zeros

PIN input and transponder within 10 seconds  ID card number with PIN code, corresp. with
PIN_MODE = 0x00

Transponder without PIN input  ID card number; corresp. with PIN_MODE = 0x00

0x02 Transponder before PIN

Transponder, LED flashes green and waits 10 seconds for key input
No PIN input: Discard and cancellation

PIN input:  ID card number with PIN code
PIN before transponder
PIN input with PIN input  as with PIN_MODE = 0x00
PIN input with E key  same as with PIN_MODE = 0x00

0x03 Enabled (disabled) mode

E key followed by transponder ID card number with identifier "B" (0x42) in PIN buffer
Pin input, E key followed by transponder ID card number with PIN code and identifier "B" in

PIN buffer
C key followed by transponder ID card number with identifier "A" (0x41) in PIN buffer
Pin input, C key followed by transponder ID card number with PIN code and identifier "A" in

PIN buffer
PIN input and transponder, without E or C key  ID card number with PIN code, corresp. with

PIN_MODE = 0x00

PIN_BUF 0x00

Only E key:  ID card number

Use of default buffer length, depending on the interface. For more information please refer to

C01

, PIN_BUF in chapter 8.

0x01 ... 0x07 Number of permissible PIN digits, autom. completion if number of digits reached; otherwise

finish with E key!

10.3.3 Clock / Data – Omron interface

 PIN input completed with E key  PIN code in ABA format
 PIN input with ID card number  ID card number with PIN code,

separator is D (0x0D), in ABA format

10.3.4 Clock / Data – Wiegand interface

 PIN input completed with E key  PIN code in BCD format
 PIN input with ID card number  ID card number with PIN code,

separator is D (0x0D), in BCD format

A different way of handling the PIN input is listed with the individual settings.

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Configuration parameters

10.4 Defining reading keys with Mifare Standard 1k and 4k

The reading key is entered into the configuration file in line Kxx.

For more information please refer to chapter 9.1 Defining parameters.

0 1 2 3 4 5

Mifare reading key no. 00 K00

Key00

0x00 0x00 0x00 0x00 0x00 0x00

Mifare reading key no. 01 K01

Key01

0xFF 0xFF 0xFF 0xFF 0xFF 0xFF

Available Mifare key numbers: 00 ... 31

The shown table is an example:

When using Mifare MAD addressing, the Mifare MAD access key has to be
configured accordingly.

The MAD access key is defined in the MAD specification: A0, A1, A2, A3, A4, A5

0 1 2 3 4 5

Mifare reading key no. xx

Kxx

Key00

0xA0 0xA1 0xA2 0xA3 0xA4 0xA5

The access key for the MAD-addressed block has to be configured additionally.
(This access key can be freely assigned by the user or is defined when the ID
cards are generated and personalized into the described cards).

0 1 2 3 4 5

Mifare reading key no. yy Kyy

Key00

0xaa 0xbb 0xcc 0xdd 0xee 0xff

 With Mifare cards, a corresponding key (access key) is required in the card reader to read data in

(a) sector(s).

 If reading access keys for the sector (directly addressed access) or the reading access keys for the

MAD sector and the data sector (indirect access via MAD) are not loaded into the card reader, the
Mifare cards cannot be read by the card reader.

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Appendix

11 Appendix

11.1 Definition of Clock/Data interfaces

11.1.1 Omron 5 bit, Magstripe Track II

Signal diagram:

Before and after data transmission there will be no output of clock pulses (clock,
without data).

1010

t

n

t

a

t

b

/CLOCK

/DATA

/CLS

t

v

t

s

0

tn

≈ 1 ms

t

a(n)

≈ t

n

/ 3

t

b(n)

≈ t

n

/ 2

tv = ts 10 ... 12 ms

Structure of information:

According to ISO7811-2 Track 2 (start sentinel, data, stop sentinel, LRC)

Data format: 5 bit, (4 Data bits, 1 parity).

11.1.2 Wiegand

Signal diagram:

45

/CLOCK = DATA0

/DATA = DATA1

/

CLS

t

v

ts

1 1 1

0 0 0

t

n

t

n

≈ 1 ms

tv = ts 10 ... 12 ms

Structure of information:

The characters/digits read out of cards (transponder) will be transmitted directly 1:1
(no change) without adding any information frames.

If there is a special format required, the ID No. on the ID card can be adjusted.

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Appendix

11.2 Dimensions for flush mounting

All dimensions in mm.

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Appendix

11.3 Dimensions for surface mounting with distance frame

All dimensions in mm.

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Appendix

11.4 Addressing / Address setting: Mifare 1k

Block number (Hex) Sector Block Block number (Hex) Sector Block

0 ( 00 ) 0 0 24 ( 18 ) 8 0
1 ( 01 ) 0 1 25 ( 19 ) 8 1
2 ( 02 ) 0 2 26 ( 1A ) 8 2
3 ( 03 ) 1 0 27 ( 1B ) 9 0
4 ( 04 ) 1 1 28 ( 1C ) 9 1
5 ( 05 ) 1 2 29 ( 1D ) 9 2
6 ( 06 ) 2 0 30 ( 1E ) 10 0
7 ( 07 ) 2 1 31 ( 1F ) 10 1
8 ( 08 ) 2 2 32 ( 20 ) 10 2

9 ( 09 ) 3 0 33 ( 21 ) 11 0
10 ( 0A ) 3 1 34 ( 22 ) 11 1
11 ( 0B ) 3 2 35 ( 23 ) 11 2

12 ( 0C ) 4 0 36 ( 24 ) 12 0
13 ( 0D ) 4 1 37 ( 25 ) 12 1

14 ( 0E ) 4 2 38 ( 26 ) 12 2
15 ( 0F ) 5 0 39 ( 27 ) 13 0
16 ( 10 ) 5 1 40 ( 28 ) 13 1
17 ( 11 ) 5 2 41 ( 29 ) 13 2
18 ( 12 ) 6 0 42 ( 2A ) 14 0
19 ( 13 ) 6 1 43 ( 2B ) 14 1
20 ( 14 ) 6 2 44 ( 2C ) 14 2
21 ( 15 ) 7 0 45 ( 2D ) 15 0
22 ( 16 ) 7 1 46 ( 2E ) 15 1
23 ( 17 ) 7 2 47 ( 2F ) 15 2

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Appendix

11.5 EC Declaration of Conformity

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Keyword index

12 Keyword index

A G

Address setting Gasket 10, 11

Clock/Data 15

H

Address setting

Housing

for RS485 bus operation 14, 32

Opening 8

Address setting for RS485 bus operation 32

HyperTerminal 25

Approval 5

I

ASCII format 23

B

ID number 21
Information to be read

BCD format 22

ID number Wiegand format compliant 16

C

ID number, BCD (4 bit) or ASCII (7 bit) coded
data 17

Card reader

Configuration 24

ID number, BCD (4 bit) or SIPASS (7 bit) coded
data 17

Clock/Data interface 13, 45

Serial number 16

Combination options 37
Commands 29

Installation 8, 9, 10, 11

Communication interface

ISO14443A Proximity read range 19

Selection 15

ISO14443A+B Proximity read range 19

Config parameters 19, 20, 25, 33

ISO15693 Vicinity read range 20

C00 33

L

C01 34

LED 12

C02 35

O

C03 35
C04 36

Output data formats 32

C05 36

P

C06 36

ConfigCard parameters 33

PIN code 42

Configuration

Power supply 13

Card reader 24

Protocol selection 15

Configuration mode

R

HyperTerminal 27

Reader interface 32

Configuration parameters 33

Reading key 25, 44

Connecting 12

RS485 interface 13

D

S

Declaration of Conformity 49

Serial number 21

Defining parameters 25

Setting the address (Clock/Data) 32

Dimensions 46, 47

T

DIP switch

Settings 14

Technical specifications 7

Display elements 12

Terminal program 25, 29

F

Transponder 18

Data formats 22

Format

Information 20

ASCII 23

Transponder types 16, 19, 21

BCD 22

W

Wiegand 23

Wiegand format 23

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Issued by
Siemens Building Technologies
Fire & Security Products GmbH & Co. oHG
D-76181 Karlsruhe

www.sbt.siemens.com

© 2004 Copyright by

Siemens Building Technologies AG

Data and design subject to change without notice.

Supply subject to availability.

Printed in the Federal Republic of Germany

on environment-friendly chlorine-free paper.

Dokument Nr. A24205-A335-B249
Ausgabe 12.2004