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Electronic Telephone Cards: How to make your own! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ I guess that Sweden is not the only country that employs the electronic phone card system from Schlumberger Technologies. This article will explain a bit about the cards they use, and how they work. In the end of this article you will also find an UUEncoded file which contains sourcecodes for a PIC16C84 microcontroller program that completely emulate a Schlumberger Telephone card and of course printed circuit board layouts + component list... But before we begin talking seriously of this matter I must first make it completely clear that whatever you use this information for, is entirely YOUR responsibility, and I cannot be held liable for any problems that the use of this information can cause for you or for anybody else. In other words: I give this away FOR FREE, and I don't expect to get ANYTHING back in return! The Original Telephone Card: ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Since I probably would have had a hard time writing a better article than the one Stephane Bausson from France wrote a while ago, I will not attempt to give a better explanation than that one; I will instead incorporate it in this phile, but I do want to make it clear that the following part about the cards technical specification was not written by me: Merely the parts in quotes are things added by me... Instead I will concentrate on explaining how to build your own telephone card emulator and how the security measures in the payphone system created by Schlumberger Technologies work, and how to trick it... But first, let's have a look at the technical specifications of the various "smart memory card" systems used for the payphones. <Start of text quoted from Stephane Bausson (sbausson@ensem.u-nancy.fr)> ------------------------------------------------------------------------------ =============================================================================== What you need to know about electronics telecards =============================================================================== (C) 10-07-1993 / 03-1994 Version 1.06 Stephane BAUSSON Email: sbausson@ensem.u-nancy.fr Smail: 4, Rue de Grand; F-88630 CHERMISEY; France Phone: (33)-29-06-09-89 ------------------------------------------------------------------------------- Any suggestions or comments about phonecards and smart-cards are welcome ------------------------------------------------------------------------------- Content --------- I ) The cards from Gemplus, Solaic, Schlumberger, Oberthur: I-1) Introduction: I-2) SCHEMATICS of the chip: I-3) PINOUT of the connector: I-4) Main features: I-5) TIME DIAGRAMS: I-6) Memory MAP of cards from France and Monaco: I-5) Memory MAP of cards from other countries: II ) The cards from ODS: (German cards) II-1) Introduction: II-2) Pinout: II-3) Main features: II-4) Time Diagrams: II-5) Memory Map: II-6) Electrical features: III) The Reader Schematic: IV) The program: ------------------------------------------------------------------------------- I ) The cards from Gemplus, Solaic, Schlumberger, Oberthur: (French cards) ====================================================================== I-1) Introduction: ------------ You must not think that the electronics phone-cards are completly secret things, and that you can not read the informations that are inside. It is quite false, since in fact an electronic phonecard does not contain any secret information like credit cards, and an electronic phonecard is nothing else that an 256 bits EPROM, with serial output. Besides do not think that you are going to refilled them when you will have understood how they work, since for that you should reset the 256 bits of the cards by erasing the whole card. But the chip is coated in UV opaqued resin even if sometime you can see it as tranparent! Even if you were smart enough to erase the 256 bits of the card you should program the manufactuer area, but this is quite imposible since these first 96 bits are writing protected by a lock-out fuse that is fused after the card programing in factory. Neithertheless it can be very interesting to study how these cards work, to see which kind of data are inside and how the data are maped inside or to see how many units are left inside for exemple. Besides there are a great number of applications of these cards when there are used (only for personal usage of course) , since you can use them as key to open a door, or you can also use them as key to secure a program, etc .... These Telecards have been created in 1984 and at this time constructors decided to build these cards in NMOS technology but now, they plan to change by 1994 all readers in the public to booths and use CMOS technology. Also they plan to use EEPROM to secure the cards and to add many usefull infornations in, and you will perhaps use phone cards to buy you bread or any thing else. These cards are called Second Generation Telecards. I-2) SCHEMATICS of the chip: ---------------------- .-------------------. | | --|> Clk | | _ | --| R/W | | | --| Reset | | | --| Fuse | | | --| Vpp | | | | | '-. .-' | | .-------------------. | Out |-- serial output '-------------------' I-3) PINOUT of the connector: ------------------------- AFNOR CHIP ISO CHIP ---------- -------- -------------+------------- -------------+------------- | 8 | 4 | | 1 | 5 | | | | | | | +-------\ | /-------+ +-------\ | /-------+ | 7 +----+----+ 3 | | 2 +----+ + 6 | | | | | | | | | +--------| |--------+ +--------| |--------+ | 6 | | 2 | | 3 | | 7 | | + +----+ | | +----+----+ | +-------/ | \-------+ +-------/ | \-------+ | 5 | 1 | | 4 | 8 | | | | | | | -------------+------------- -------------+------------- NB: only the position of the chip is ISO standardized and not the pinout PINOUT: 1 : Vcc = 5V 5 : Gnd ------ 2 : R/W 6 : Vpp = 21V 3 : Clock 7 : I/O 4 : Reset 8 : Fuse I-4) Main features: --------------- - Synchronous protocol. - N-MOS technology. - 256x1 bit organisation. - 96 written protected by a lock-out fuse. - Low power 85mW in read mode. - 21 V programming voltage. - Access time: 500ns - Operating range: -10?C +70?C - Ten year data rentention. I-5) TIME DIAGRAMS: --------------- +21V _____________ +5V ____________________________________| |_________________ Vpp : : +5V ___________________:_____________:_________________ Reset 0V ________________| : : : : : +5V ____ : ____ : ______:______ 0V ___| |_______:_____| |________:______| : |__________ Clock : : : : : : : : : +5V : : : : : :______:______: : _ 0V ___:____:_______:_____:____:________| : |______:__________ R/W : : : : : : : : : +5V : : :_____: :________: : : :__________ 0V XXXXXXXXXXXXXXXXX_____XXXXXX________XXXXXXXXXXXXXXXXXXXXXX__________ Out : : : : : :<-----><---->: : : : : : : :10 to 10 to : : : : : : :50 ms 50ms : Reset Bit 1 Bit2 Bit 3 card reading reading Bit2 writing to 1 reading I-6) MEMORY MAP of cards from France and Monaco: -------------------------------------------- Bytes Bits Binary Hexa +-----------+-----+ 1 1 --> 8 | | | ---> Builder code. +-----------+-----+ 2 9 --> 16 | 0000 0011 | $03 | ---> a french telecard +-----------+-----+ 3 17 --> 24 | | | +-----------+-----+ 4 25 --> 32 | | | +-----------+-----+ 5 33 --> 40 | | | +-----------+-----+ 6 41 --> 48 | | | +-----------+-----+ 7 49 --> 56 | | | +-----------+-----+ 8 57 --> 64 | | | +-----------+-----+ 9 65 --> 72 | | | +-----------+-----+ 10 73 --> 80 | | | +-----------+-----+ 11 81 --> 88 | | | +-----------+-----+ 12 33 --> 40 | 0001 0011 | $13 | ---> 120 units card | 0000 0110 | $06 | ---> 50 units card | 0000 0101 | $05 | ---> 40 units card +-----------+-----+ 13-31 97 --> 248 | | | ---> The units area: each time a unit | | | is used, then a bit is set to "1"; | | | Generaly the first ten units are | | | fused in factory as test. | | | | | | | | | +-----------+-----+ 32 249 --> 256 | 1111 1111 | $FF | ---> the card is empty +-----------+-----+ I-7) MEMORY MAP of the other cards: ------------------------------- Bytes Bits Binary Hexa +-----------+-----+ 1 1 --> 8 | | | +-----------+-----+ 2 9 --> 16 | 1000 0011 | $83 | ---> a telecard +-----------+-----+-----------+-----+ 3-4 17 --> 32 | 1000 0000 | $80 | 0001 0010 | $12 | ---> 10 units card | | | 0010 0100 | $24 | ---> 22 units card | | | 0010 0111 | $27 | ---> 25 units card | | | 0011 0010 | $32 | ---> 30 units card | | | 0101 0010 | $52 | ---> 50 units card | | | 1000 0010 | $82 | ---> 80 units card | 1000 0001 | $81 | 0000 0010 | $02 | ---> 100 untis card | | | 0101 0010 | $52 | ---> 150 units card +-----------+-----+-----------+-----+ 5 33 --> 40 | | | +-----------+-----+ 6 41 --> 48 | | | +-----------+-----+ 7 49 --> 56 | | | +-----------+-----+ 8 57 --> 64 | | | +-----------+-----+ 9 65 --> 72 | | | +-----------+-----+ 10 73 --> 80 | | | +-----------+-----+ 11 81 --> 88 | | | +-----------+-----+ 12 89 --> 96 | 0001 1110 | $1E | ---> Sweden | 0010 0010 | $22 | ---> Spain | 0011 0000 | $30 | ---> Norway | 0011 0011 | $33 | ---> Andorra | 0011 1100 | $3C | ---> Ireland | 0100 0111 | $47 | ---> Portugal | 0101 0101 | $55 | ---> Czech Republic | 0101 1111 | $5F | ---> Gabon | 0110 0101 | $65 | ---> Finland +-----------+-----+ 13-31 97 --> 248 | | | ---> The units area: each time a unit | | | is used, then a bit is set to "1"; | | | | | | Generaly the first two units are | | | fused in factory as test. | | | | | | +-----------+-----+ 32 249 --> 256 | 0000 0000 | $00 | +-----------+-----+ II ) The cards from ODS, Giesecke & Devrient, ORGA Karten systeme, ============================================================= Uniqua, Gemplus, Schlumberger and Oldenbourg Kartensysteme: =========================================================== II-1) Introduction: ------------ These cards are in fact 128 bit memory in NMOS technology, and the map of these cards are the following: 64 bit EPROM written protected (manufaturer area). 40 bit EEPROM (5x8 bits). 24 bits set to "1". II-2) Pinout: -------- ISO 7816-2 -------------+------------- | 1 | 5 | Pinout: | | | ------- +-------\ | /-------+ | 2 +----+ + 6 | 1 : Vcc = 5V 5 : Gnd | | | | 2 : Reset 6 : n.c. +--------| |--------+ 3 : Clock 7 : I/O | 3 | | 7 | 4 : n.c. 8 : n.c. | +----+----+ | +-------/ | \-------+ n.c. : not connected | 4 | 8 | | | | -------------+------------- II-3) Main features: --------------- - ISO 7816- 1/2 compatible. - use a single 5V power supply. - low power consuption. - NMOS technology. II-4) Time Diagrams: ---------------- Reset: ------ The address counter is reset to 0 when the clock line CLK is raised while the control line R is high. Note that the address counter can not be reset when it is in the range 0 to 7. __________________ _____| |_____________________________________________ Reset : : : _____ : _____ _____ _____ _____ _____:_______| |____:_| |_____| |_____| |_____| |_ Clk : : : : : : : : : : : _____:_______:__________:_:_____:_____:_____:_____:_____:_____:_____:_ _____:___n___|_____0____:_|_____1_____|_____2_____|_____3_____|___4_:_ (Address) : : : : : : _____: :_______:___________:___________:___________:_ _____XXXXXXXXXXXXXXXXXXXX_______|___________|___________|___________|_ Data Bit n Bit 0 Bit 1 Bit2 Bit3 The address counter is incremented by 1 with each rising edge of the clock signal Clk, for as long as the control line R remains low. The data held in each addressed bit is output to I/O contact each time Clk falls. It is not impossible to decrement the address counter, therefore to address an earlier bit, the address counter must be reset then incremented to require value. Write: ------ All unwritten or erased bits in the address 64-104 may be unwritten to. When a memory cell is unwritten to, it is set to 0. The addressed cell is unwritten to by the following sequence. 1- R is raised while Clk is low, to disable address counter increment for one clock pulse. 2- Clk is then raised for a minimum of 10ms to write to the address bit. When to write operation ends, and Clk falls, the address counter is unlocked, and the content of the written cell, which is now 0, is output to I/O contact if the operation is correct. The next Clk pulse will increment the address by one, then the write sequence can be repeated to write the next bit. _____ _____ _____________| |______________________________| |_______________ Reset : : ___ : _____ ___ : _____ ____| |____:__________| |_________| |_____:__________| |____ Clk : : : : : : : : : ____:________:__________:_____:_________:___:_____:__________:_____:_____ n | n+1 | n+2 | : n+3 | : (Address) ----'--------:----------'-----:---------'---:-----:----------'-----:----- : : : : : : : _________ _: : : ____________: ___: : : _________XXX_XXXXXXXXXXXXXXXXXXX____________ XX___XXXXXXXXXXXXXXXXXXXXXXX I/O n n+1 : : n+1 n+2 : : : : : : write write WriteCarry: ----------- A counter is erased by performing the WRITECARRY sequence on the stage of the next highest weighing to that to be erased. The writecarry sequence is as follows: 1 - Set the address counter to an unwritten bit in the next highest counter stage to that to be erased. 2 - Increment is disabled on the following rising edge of R where Clk remains low. 3 - Clk is then raised for a minimum of 10ms, while R is low, to write to the next address bit. 4 - R is the raised again while Clk remains low to disable increment a second time. 5 - Clk is the raised for a minimum of 1ms, while R is low, to write to the addressed bit a second time, erasing the counter level immediately below that the addressed bit. _____ _____ ______| |____________________| |_________________________________ Rst : : : _______ : _______ ___ ______:___________| |______:_____________| |______| |______ Clk : : : : : : : : : : : : : : : : <------------------------- address n ------------------------>:<--- n+1 ------ : : : : : : : : : : : : : : ______: : :______: : :__________: _____ ______XXXXXXXXXXXXXXXXXXXXX______XXXXXXXXXXXXXXXXXXXXXXX__________XX_____ I/O : : n : : n n+1 : : : : Write Erase II-5) Memory Map: ------------- Bytes Bits Binary Hexa +-----------+-----+ 1 1 --> 8 | | | +-----------+-----+ 2 9 --> 16 | 0010 1111 | $2F | ---> Germany | 0011 0111 | $37 | ---> Netherland | 0011 1011 | $3B | ---> Greece +-----------+-----+ 3 17 --> 24 | | | 4 25 --> 32 | | | ---> Issuer area (written protected) 5 33 --> 40 | | | 6 41 --> 48 | | | 7 49 --> 56 | | | 8 57 --> 64 | | | +-----------+-----+ 9 65 --> 72 | | | ---> c4096 ) 10 73 --> 80 | | | ---> c512 ) 11 81 --> 88 | | | ---> c64 ) 5 stage octal counter 12 89 --> 96 | | | ---> c8 ) 13 97 --> 104 | | | ---> c0 ) +-----------+-----+ 14 105 --> 112 | 1111 1111 | $FF | 15 113 --> 120 | 1111 1111 | $FF | ---> area of bits set to "1" 16 120 --> 128 | 1111 1111 | $FF | +-----------+-----+ The Issuer area: ---------------- This issuer consists of 40 bits. The contents of the issuer area are specified by the card issuer, and are fixed during the manufacturing process. The contents of the issuer area will include data such as serial numbers, dates, and distribution centers. This area may only be read. The Counter area: ----------------- The counter area stores the card's units. Its initial value is specified by the card issuer and set during manufacturing. The counter area is divided into a 5 stage abacus. Note that you can only decrease the counter and it is not authorised to write in the counter a value greater than the old value. I-6) Electrical features: -------------------- Maximum ratings: ---------------- +--------+------+------+------+ | Symbol | Min | Max | Unit | +----------------------+--------+------+------+------+ | Supply voltage | Vcc | -0.3 | 6 | V | +----------------------+--------+------+------+------+ | Input voltage | Vss | -0.3 | 6 | V | +----------------------+--------+------+------+------+ | Storage temperature | Tstg | -20 | +55 | ?C | +----------------------+--------+------+------+------+ | Power dissipassion | Pd | - | 50 | mW | +----------------------+--------+------+------+------+ DC caracteristics: ------------------ +--------+-----+-----+-----+------+ | Symbol | Min.| Typ.| Max.| Unit | +---------------------------+--------+-----+-----+-----+------+ | Suplly current | Icc | - | - | 5 | mA | +---------------------------+--------+-----+-----+-----+------+ | Input Voltage (low) | Vl | 0 | - | 0.8 | V | +---------------------------+--------+-----+-----+-----+------+ | Input voltage (high) | Vh | 3.5 | - | Vcc | V | +---------------------------+--------+-----+-----+-----+------+ | Input current R | Ih | - | - | 100 | uA | +---------------------------+--------+-----+-----+-----+------+ | Input current Clk | Il | - | - | 100 | uA | +---------------------------+--------+-----+-----+-----+------+ | Output current (Vol=0.5V) | Iol | - | - | 10 | uA | +---------------------------+--------+-----+-----+-----+------+ | Output current (Voh=5V) | Ioh | - | - | 0.5 | mA | +---------------------------+--------+-----+-----+-----+------+ AC caracteristics: ------------------ +--------+------+------+------+ | Symbol | Min. | Max. | Unit | +----------------------+--------+------+------+------+ | Pulse duration | tr | 50 | - | us | | R address reset | | | | | +----------------------+--------+------+------+------+ | Pulse duration | ts | 10 | - | us | | R write | | | | | +----------------------+--------+------+------+------+ | High level Clk | th | 8 | - | us | +----------------------+--------+------+------+------+ | Low level Clk | tl | 12 | - | us | +----------------------+--------+------+------+------+ | Write window | Twrite | 10 | - | ms | +----------------------+--------+------+------+------+ | Erase window | Terase | 10 | - | ms | +----------------------+--------+------+------+------+ | | tv1 | 5 | - | us | +----------------------+--------+------+------+------+ | | tv2 | 3.5 | - | us | +----------------------+--------+------+------+------+ | | tv3 | 3.5 | - | us | +----------------------+--------+------+------+------+ | | tv4 | 3.5 | - | us | +----------------------+--------+------+------+------+ | | tv5 | 3.5 | - | us | +----------------------+--------+------+------+------+ | | tv6 | 5 | - | us | +----------------------+--------+------+------+------+ | | tv7 | 5 | - | us | +----------------------+--------+------+------+------+ | | tv8 | 10 | - | us | +----------------------+--------+------+------+------+ III) The Reader Schematic: ====================== External 5V (Optional) 5V o------, | / T2 PNP d13 r7 10 0V o--, | / BC 177 |\ | _____ | | ,-------o/ o--*------. E C .--| >+-[_____]--------, __+__ | | | \ / |/ | | \\\\\ | __|__ Batery | \ / | | - 22.5V | --------- | ....... | | | _____ | _____ | : | __+__ +--[_____]--*--[_____]--, | D2 : | \\\\\ r6 150k r5 15k | | 4 o-------|---------------------------*------------------|-------------, | : | | r3 220k / C | | Ack : | | _____ |/ T1 - NPN | | 10 o------|--------. '--[_____]-*---| BC107 | | : | | _____ | |\ | | : ,-, ,-, +--[_____]-' \ E | | : | |r2 | |r1 | r4 390k | | | : | |220 | |22k __+__ __+__ | | : |_| |_| \\\\\ \\\\\ | | : | |\ | | | | : *--| >+--|----------------*----------------------------------|--* : | |/ | | ,-----|-----------------------------, | | : | d1 | | | ,----------,----------, | | | : | | | *---|--* Fuse | Reset *--|---' | | : | | | | |----------|----------| | | D0 : | | | ,-|---|--* I/O | Clk *--|---, | | 2 o-------|--------|----------' | | |----------|----------| | | | : | | | '---|--* Vpp | R/W *--|---|----' | Busy : | | | |----------|----------| | | 11 o------|--------|--------------' ,---|--* Gnd | 5V * | | | : | | | '----------'-------|--' | | D1 : | | __+__ Chip connector | | | 3 o-------|--------|--------, \\\\\ | | | : | | '------------------------------|------' | Str : | |\ | | | | 1 o-------*--| >+--*----*----*----*----*-------------------' | : d2|/ | |d3 |d4 |d5 |d6 |d7 | : -+- -+- -+- -+- -+- | : /_\ /_\ /_\ /_\ /_\ | D3 : | | | | | |\ | d8 | 5 o----------------*----|----|----|----|---| >+-------*-------------------' : | | | | |/ | | : | | | | | D4 : | | | | |\ | d9 | 6 o---------------------*----|----|----|---| >+-------* : | | | |/ | | : | | | | D5 : | | | |\ | d10 | 7 o--------------------------*----|----|---| >+-------* : | | |/ | | : | | | D6 : | | |\ | d11 | 8 o-------------------------------*----|---| >+-------* : | |/ | | : | | D7 : | |\ | d12 | 9 o------------------------------------*---| >+-------' : |/ | : : 25 o------. : | .......: | d1 to d13: 1N4148 __+__ \\\\\ Centronic port IV) The program: =========== The following program will enable you to read telecards on you PC if you build the precedent reader. --------------- cut here (begin) {*****************************************************************************} { T E L E C A R D . PAS } {*****************************************************************************} { This program enable you to dumb the memory of electronics phonecards } { from all over the world, so that you will be able to see which country } { the card is from how many units are left and so on .... } {*****************************************************************************} { } { Written by Stephane BAUSSON (1993) } { } { Email: sbausson@ensem.u-nancy.fr } { } { Snail Mail Address: 4, Rue de Grand } { F-88630 CHERMISEY } { France } { } {*****************************************************************************} {* Thanks to: Tomi Engdahl (Tomi.Engdahl@hut.fi) *} {*****************************************************************************} USES crt,dos; CONST port_address=$378; { lpr1 chosen } TYPE string8=string[8]; string2=string[2]; VAR reg : registers; i,j : integer; Data : array[1..32] of byte; car : char; byte_number : integer; displaying : char; {-----------------------------------------------------------------------------} PROCEDURE Send(b:byte); BEGIN port[port_address]:=b; END; {-----------------------------------------------------------------------------} FUNCTION Get:byte; BEGIN get:=port[port_address+1]; END; {-----------------------------------------------------------------------------} { FUNCTION dec2hexa_one(decimal_value):hexa_character_representation; } { } { - convert a 4 bit long decimal number to hexadecimal. } {-----------------------------------------------------------------------------} FUNCTION dec2hexa_one(value:byte):char; BEGIN case value of 0..9 : dec2hexa_one:=chr(value+$30); 10..15 : dec2hexa_one:=chr(value+$37); END; END; {-----------------------------------------------------------------------------} { FUNCTION d2h(decimal_byte):string2; } { } { - convert a decimal byte to its hexadecimal representation. } {-----------------------------------------------------------------------------} FUNCTION d2h(value:byte):string2; VAR msbb,lsbb:byte; BEGIN msbb:=0; if ( value >= $80 ) then BEGIN msbb:=msbb+8; value:=value-$80; END; if ( value >= $40 ) then BEGIN msbb:=msbb+4; value:=value-$40; END; if ( value >= $20 ) then BEGIN msbb:=msbb+2; value:=value-$20; END; if ( value >= $10 ) then BEGIN msbb:=msbb+1; value:=value-$10; END; lsbb:=0; if ( value >= $08 ) then BEGIN lsbb:=lsbb+8; value:=value-$08; END; if ( value >= $04 ) then BEGIN lsbb:=lsbb+4; value:=value-$04; END; if ( value >= $02 ) then BEGIN lsbb:=lsbb+2; value:=value-$02; END; if ( value >= $01 ) then BEGIN lsbb:=lsbb+1; value:=value-$01; END; d2h := dec2hexa_one(msbb) + dec2hexa_one(lsbb); END; {-----------------------------------------------------------------------------} Function Binary( b : byte):string8; var weigth : byte; s : string8; BEGIN weigth:=$80; s:=''; while (weigth > 0) do BEGIN if ((b and weigth) = weigth) then s:=s+'1' else s:=s+'0'; weigth:=weigth div $02; END; Binary:=s; END; {-----------------------------------------------------------------------------} FUNCTION Units:byte; VAR u, i : integer; s : string8; BEGIN u:=0; i:=13; while (Data[i] = $FF) do BEGIN u:=u+8; i:=i+1; END; s:=Binary(Data[i]); while(s[1]='1') do BEGIN inc(u); s:=copy(s,2,length(s)); END; units:=u; END; {-----------------------------------------------------------------------------} function Units_2:LongInt; BEGIN Units_2:=4096*Data[9]+512*Data[10]+64*Data[11]+8*Data[12]+Data[13]; END; {-----------------------------------------------------------------------------} PROCEDURE Card_Type; BEGIN case Data[2] of $03: BEGIN write('Telecard - France - '); case Data[12] of $13: write('120 Units - ',units-130,' Units left'); $06: write('50 Units - ',units-60,' Units left'); $15: write('40 Units - ',units-40,' Units left'); END; END; $2F:BEGIN write('Telecard - Germany - ', Units_2, ' Units left'); END; $3B:BEGIN write('Telecard - Greece - ', Units_2, ' Units left'); END; $83:BEGIN write('Telecard'); case Data[12] of $1E: write(' - Sweden'); $30: write(' - Norway'); $33: write(' - Andorra'); $3C: write(' - Ireland'); $47: write(' - Portugal'); $55: write(' - Czech Republic'); $5F: write(' - Gabon'); $65: write(' - Finland'); END; if (Data[12] in [$30,$33,$3C,$47,$55,$65]) then BEGIN case ((Data[3] and $0F)*$100+Data[4]) of $012: write (' - 10 Units - ',units-12,' Units left'); $024: write (' - 22 Units - ',units-24,' Units left'); $027: write (' - 25 Units - ',units-27,' Units left'); $032: write (' - 30 Units - ',units-32,' Units left'); $052: write (' - 50 Units - ',units-52,' Units left'); $067: write (' - 65 Units - ',units-62,' Units left'); $070: write (' - 70 Units - ',units-70,' Units left'); $102: write (' - 100 Units - ',units-102,' Units left'); $152: write (' - 150 Units - ',units-152,' Units left'); END; END; { write(' - N? ',Data[5]*$100+Data[6]);} END; END; END; {-----------------------------------------------------------------------------} PROCEDURE waiting; BEGIN send($00); write('Enter a card in the reader and press a key ...'); repeat until keypressed; gotoxy(1, wherey); clreol; END; {-----------------------------------------------------------------------------} PROCEDURE Full_Displaying; BEGIN writeln('Memory dump:'); for i:=1 to 80 do write('-'); for i:=1 to (byte_number div 6 + 1) do BEGIN for j:=1 to 6 do BEGIN if j+6*(i-1) <= byte_number then write(binary(Data[j+6*(i-1)]):9); END; gotoxy(60,wherey); for j:=1 to 6 do if j+6*(i-1) <= byte_number then write(d2h(Data[j+6*(i-1)]),' '); writeln; END; for i:=1 to 80 do write('-'); Card_Type; writeln; END; {-----------------------------------------------------------------------------} PROCEDURE Short_Displaying; VAR j : integer; BEGIN for j:=1 to byte_number do BEGIN write(d2h(Data[j]),' '); END; writeln; END; {-----------------------------------------------------------------------------} PROCEDURE Reading; VAR i, j : integer; Value : byte; BEGIN send($FE); send($F8); for i:=1 to 32 do BEGIN Value:=0; for j:=1 to 8 do BEGIN Value:=Value*$02 + ((get and $08) div $08); send($FB); delay(1); send($F8); END; Data[i]:=Value; END; case displaying of 'F':full_displaying; 'S':short_displaying; END; END; {-----------------------------------------------------------------------------} PROCEDURE writting; VAR i,n:integer; car:char; BEGIN write('Which bit do you want to set to "1" : '); readln(n); waiting; car:=readkey; send($FA); send($F8); for i:=1 to n do BEGIN send($F9); if i=n then BEGIN send($FD); delay(20); send($FF); delay(20); END; send($FB); END; reading; END; {-----------------------------------------------------------------------------} PROCEDURE Saving; VAR filename : string; f : text; i : word; BEGIN write('Enter the filename: '); readln(filename); assign(f, filename); rewrite(f); for i:=1 to byte_number do write(f,d2h(Data[i]),' '); close(f); END; {-----------------------------------------------------------------------------} PROCEDURE initialize; VAR i : integer; BEGIN byte_number:=32; displaying:='F'; clrscr; writeln(' 1 - to dump a 256 bits card'); writeln(' 2 - to dump a 128 bits card'); writeln(' F - to display in full format'); window(41,1,80,25); writeln(' S - to display in short format'); writeln(' F2 - to save in a file'); writeln(' Q - to exit the program'); window(1,4,80,25); for i:=1 to 80 do write('='); window(1,5,80,25); END; {=============================================================================} BEGIN initialize; repeat waiting; car:=upcase(readkey); case car of 'W':writting; 'Q':; '1':byte_number:=32; '2':byte_number:=16; 'F','S':displaying:=car; #00: BEGIN car:=readkey; if car=#60 then saving; END; else reading; END; until car='Q'; END. --------------- cut here (end) _/_/_/_/_/ Stephane BAUSSON _/_/_/_/_/ Engineering student at ENSEM (Nancy - France) _/_/_/_/_/ Smail: 4, Rue de Grand, F-88630 CHERMISEY, France _/_/_/_/_/ _/_/_/_/_/ Email: sbausson@ensem.u-nancy.fr ------------------------------------------------------------------------------ <End of text quoted from Stephane Bausson's text about the telephone cards>. The Program: ~~~~~~~~~~~~ Well, when I saw this phile about the cards the first time, about a year ago I quickly realized that this system is very unsecure and really needs to be hacked. So, now I present you with a piece of software for the PIC 16C84 RISC microcontroller from Microchip that will take care of emulating the cards used by Schlumberger and others. This system is to be found in Scandinavia (Sweden, Norway and Finland), Spain, France and other countries. I do know that France probably needs some small modifications for this to work, but I see no reason to as why it shouldn't do so! For this to work, you need to have access to a PROM burner which can handle the PIC 16C84, or you might just build one yourself as I include some plans for that in the UUEncoded block to be found at the end of this phile. First of all, you have to read off the first 12 bytes of data from a valid card from the country you wish your emulator to work in. This because I don't think it would be a good idea to publish stolen card identities in Phrack. Then you simply enter those 12 bytes of data in the proper place in my program and compile it. That's it... And since I happen to choose a version of the PIC with internal Data EEPROM, that means that the first 12 locations of the Data EEPROM should contain the card id bytes. As of today this code should work smooth and fine, but maybe you'll need to modify it later on when Schlumberger gets tired of my hack. But since the PIC is a very fast and powerful microcontroller it might be quite hard for them to come up with a solution to this problem. Let's have a look at the PIC Software! (Note that the current version of Microchip's PICSTART 16B package is unable to program the DATA EEPROM array in the 16C84 so if you are going to use that one, use the other version of the source code which you'll find in the UUEncoded part!). <Start of TELECARD.ASM>. ============================================================================== TITLE "ISO 7816 Synchronous Memory Card Emulator" LIST P=PIC16C84, R=HEX INCLUDE "PICREG.EQU" ; PIC16C84 I/O Pin Assignment List CRD_CLK equ 0 ; RB0 + RA4 = Card Clock CRD_DTA equ 0 ; RA0 = Card Data Output CRD_RST equ 1 ; RB1 = Card Reset, Low-Active CRD_WE equ 7 ; RB7 = Card Write-Enable, Hi-Active ; PIC16C84 RAM Register Assignments CRD_ID equ 0x00c ; Smartcard ID, 12 bytes FUSCNT equ 0x018 ; Fused units counter BITCNT equ 0x019 ; Bitcounter LOOPCNT equ 0x01a ; Loop Counter EE_FLAG equ 0x01b ; EEPROM Write Flag TEMP1 equ 0x01c ; Temporary Storage #1 TEMP2 equ 0x01d ; Temporary Storage #2 TEMP3 equ 0x01e ; Temporary Storage #3 TEMP4 equ 0x01f ; Temporary Storage #4 TEMP_W equ 0x02e ; Temporary W Save Address TEMP_S equ 0x02f ; Temporary STATUS Save Address org 0x2000 ; Chip ID Data dw 042,042,042,042 org 0x2007 ; Configuration Fuses dw B'00000001' org 0x2100 ; Internal Data EEPROM Memory (Card ID!!!) db 0x081,0x042,0x000,0x011,0x022,0x033 db 0x044,0x055,0x066,0x077,0x011,0x084 db 0x002 ; Default used up credits value org PIC84 ; Reset-vector goto INIT ; Jump to initialization routine org INTVEC ; Interupt-vector push ; Save registers call INTMAIN ; Call main interupt routine pop ; Restore registers retfie ; return from interupt & clear flag org 0x010 ; Start address for init rout. INIT bsf STATUS,RP0 ; Access register bank 1 clrwdt ; Clear watchdog timer movlw B'11101000' ; OPTION reg. settings movwf OPTION ; Store in OPTION register movlw B'11111110' ; Set PORT A Tristate Latches movwf TRISA ; Store in PORT A tristate register movlw B'11111111' ; Set PORT B Tristate Latches movwf TRISB ; Store in PORT B tristate register bcf STATUS,RP0 ; Access register bank 0 clrf RTCC ; Clear RTCC clrf PORTA ; Clear PORTA clrf PORTB ; Clear PORTB movlw 0d ; 13 bytes to copy movwf LOOPCNT ; Store in LOOPCNT movlw 0c ; Start storing at $0c in RAM movwf FSR ; Store in FSR clrf EEADR ; Start at EEPROM Address 0 EECOPY bsf STATUS,RP0 ; Access register bank 1 bsf EECON1,RD ; Set EECON1 Read Data Flag bcf STATUS,RP0 ; Access register bank 0 movfw EEDATA ; Read one byte of EEPROM Data movwf INDIR ; Store in RAM pointed at by FSR incf FSR ; Increase FSR pointer incf EEADR ; Increase EEPROM Address Pointer decfsz LOOPCNT,1 ; Decrease LOOPCNT until it's 0 goto EECOPY ; Go and get some more bytes! bsf STATUS,RP0 ; Access register bank 1 bcf EECON1,EEIF ; Clear EEPROM Write Int. Flag bcf EECON1,WREN ; EEPROM Write Disable bcf STATUS,RP0 ; Access register bank 0 movlw B'10010000' ; Enable INT Interupt movwf INTCON ; Store in INTCON MAIN bsf STATUS,RP0 ; Access register bank 1 btfsc EECON1,WR ; Check if EEPROM Write Flag Set goto MAIN ; Skip if EEPROM Write is Completed bcf EECON1,EEIF ; Reset Write Completion Flag bcf EECON1,WREN ; EEPROM Write Disable bcf STATUS,RP0 ; Access register bank 0 btfss EE_FLAG,LSB ; Check for EEPROM Write Flag goto MAIN ; If not set, jump back and wait some more clrf EE_FLAG ; Clear EEPROM Write Flag movlw 0c ; Units is stored in byte $0c movwf EEADR ; Store in EEPROM Address Counter movfw FUSCNT ; Get fused units counter movwf EEDATA ; Store in EEDATA bsf STATUS,RP0 ; Access register bank 1 bsf EECON1,WREN ; EEPROM Write Enable bcf INTCON,GIE ; Disable all interupts movlw 055 ; Magic Number #1 for EEPROM Write movwf EECON2 ; Store in EECON2 movlw 0aa ; Magic Number #2 for EEPROM Write movwf EECON2 ; Store in EECON2 bsf EECON1,WR ; Execute EEPROM Write bsf INTCON,GIE ; Enable all interupts again! bcf STATUS,RP0 ; Access register bank 0 goto MAIN ; Program main loop! INTMAIN btfsc INTCON,INTF ; Check for INT Interupt goto INTMAIN2 ; If set, jump to INTMAIN2 movlw B'00010000' ; Enable INT Interupt movwf INTCON ; Store in INTCON return INTMAIN2 bcf STATUS,RP0 ; Access register bank 0 bsf PORTA,CRD_DTA ; Set Data Output High btfsc PORTB,CRD_RST ; Check if reset is low goto NO_RST ; If not, skip reset sequence movfw RTCC ; Get RTCC Value movwf TEMP4 ; Store in TEMP4 clrf RTCC ; Clear RTCC movlw 055 ; Subtract $55 from TEMP4 subwf TEMP4,0 ; to check for card reset.... bnz NO_RST2 ; If not zero, jump to NO_RST movlw 02 ; Unused one has $02 in FUSCNT movwf FUSCNT ; Store full value in FUSCNT bsf EE_FLAG,LSB ; Set EEPROM Write Flag NO_RST2 bcf INTCON,INTF ; Clear INT Interupt Flag return ; Mission Accomplished, return to sender NO_RST movfw RTCC ; Get RTCC Value movwf BITCNT ; Copy it to BITCNT movwf TEMP1 ; Copy it to TEMP1 movwf TEMP2 ; Copy it to TEMP2 movlw 060 ; Load W with $60 subwf TEMP1,0 ; Subtract $60 from TEMP1 bz CREDIT ; If it is equal to $60 bc CREDIT ; or greater, then skip to units area rrf TEMP2 ; Rotate TEMP2 one step right rrf TEMP2 ; Rotate TEMP2 one step right rrf TEMP2 ; Rotate TEMP2 one step right movlw 0f ; Load W with $f andwf TEMP2,1 ; And TEMP2 with W register movfw TEMP2 ; Load W with TEMP2 addlw 0c ; Add W with $0c movwf FSR ; Store data address in FSR movfw INDIR ; Get databyte pointed at by FSR movwf TEMP3 ; Store it in TEMP3 movlw 07 ; Load W with $07 andwf TEMP1,1 ; And TEMP1 with $07 bz NO_ROT ; If result is zero, skip shift loop ROTLOOP rlf TEMP3 ; Shift TEMP3 one step left decfsz TEMP1,1 ; Decrement TEMP1 until zero goto ROTLOOP ; If not zero, repeat until it is! NO_ROT btfss TEMP3,MSB ; Check if MSB of TEMP3 is set bcf PORTA,CRD_DTA ; Clear Data Output bcf INTCON,INTF ; Clear INT Interupt Flag return ; Mission Accomplished, return to sender CREDIT btfss PORTB,CRD_WE ; Check if Card Write Enable is High goto NO_WRT ; Abort write operation if not... btfss PORTB,CRD_RST ; Check if Card Reset is High goto NO_WRT ; Abort write operation if not... incf FUSCNT ; Increase used-up units counter bsf EE_FLAG,LSB ; Set EEPROM Write-Flag bcf INTCON,INTF ; Clear INT Interupt Flag return ; Mission Accomplished, return to sender NO_WRT movlw 060 ; Load W with $60 subwf BITCNT,1 ; Subtract $60 from BITCNT movfw FUSCNT ; Load W with FUSCNT subwf BITCNT,1 ; Subtract FUSCNT from BITCNT bnc FUSED ; If result is negative, unit is fused bcf PORTA,CRD_DTA ; Clear Data Output FUSED bcf INTCON,INTF ; Clear INT Interupt Flag return ; Mission Accomplished, return to sender END ============================================================================== <End of TELECARD.ASM>. <Start of PICREG.EQU>. ============================================================================== ; PIC16Cxx Microcontroller Include File PIC54 equ 0x1ff ; PIC16C54 Reset Vector PIC55 equ 0x1ff ; PIC16C55 Reset Vector PIC56 equ 0x3ff ; PIC16C56 Reset Vector PIC57 equ 0x7ff ; PIC16C57 Reset Vector PIC71 equ 0x000 ; PIC16C71 Reset Vector PIC84 equ 0x000 ; PIC16C84 Reset Vector INTVEC equ 0x004 ; PIC16C71/84 Interupt Vector INDIR equ 0x000 ; Indirect File Reg Address Register RTCC equ 0x001 ; Real Time Clock Counter PCL equ 0x002 ; Program Counter Low Byte STATUS equ 0x003 ; Status Register FSR equ 0x004 ; File Select Register PORTA equ 0x005 ; Port A I/O Register PORTB equ 0x006 ; Port B I/O Register PORTC equ 0x007 ; Port C I/O Register ADCON0 equ 0x008 ; PIC16C71 A/D Control Reg 0 ADRES equ 0x009 ; PIC16C71 A/D Converter Result Register EEDATA equ 0x008 ; PIC16C84 EEPROM Data Register EEADR equ 0x009 ; PIC16C84 EEPROM Address Register PCLATH equ 0x00a ; Program Counter High Bits INTCON equ 0x00b ; Interrupt Control Register TRISA equ 0x005 ; Port A I/O Direction Register TRISB equ 0x006 ; Port B I/O Direction Register TRISC equ 0x007 ; Port C I/O Direction Register ADCON1 equ 0x008 ; PIC16C71 A/D Control Reg 1 EECON1 equ 0x008 ; PIC16C84 EEPROM Control Reg. 1 EECON2 equ 0x009 ; PIC16C84 EEPROM Control Reg. 2 OPTION equ 0x001 ; Option Register MSB equ 0x007 ; Most-Significant Bit LSB equ 0x000 ; Least-Significant Bit TRUE equ 1 YES equ 1 FALSE equ 0 NO equ 0 ; Status Register (f03) Bits CARRY equ 0x000 ; Carry Bit C equ 0x000 ; Carry Bit DCARRY equ 0x001 ; Digit Carry Bit DC equ 0x001 ; Digit Carry Bit Z_BIT equ 0x002 ; Zero Bit Z equ 0x002 ; Zero Bit P_DOWN equ 0x003 ; Power Down Bit PD equ 0x003 ; Power Down Bit T_OUT equ 0x004 ; Watchdog Time-Out Bit TO equ 0x004 ; Watchdog Time-Out Bit RP0 equ 0x005 ; Register Page Select 0 RP1 equ 0x006 ; Register Page Select 1 IRP equ 0x007 ; Indirect Addressing Reg. Page Sel. ; INTCON Register (f0b) Bits RBIF equ 0x000 ; RB Port change interrupt flag INTF equ 0x001 ; INT Interrupt Flag RTIF equ 0x002 ; RTCC Overflow Interupt Flag RBIE equ 0x003 ; RB Port Ch. Interupt Enable INTE equ 0x004 ; INT Interupt Enable RTIE equ 0x005 ; RTCC Overflow Int. Enable ADIE equ 0x006 ; PIC16C71 A/D Int. Enable EEIE equ 0x006 ; PIC16C84 EEPROM Write Int. Enable GIE equ 0x007 ; Global Interupt Enable ; OPTION Register (f81) Bits PS0 equ 0x000 ; Prescaler Bit 0 PS1 equ 0x001 ; Prescaler Bit 1 PS2 equ 0x002 ; Prescaler Bit 2 PSA equ 0x003 ; Prescaler Assignment Bit RTE equ 0x004 ; RTCC Signal Edge Select RTS equ 0x005 ; RTCC Signal Source Select INTEDG equ 0x006 ; Interupt Edge Select RBPU equ 0x007 ; Port B Pull-up Enable ; ADCON0 Register (f08) Bits ADON equ 0x000 ; A/D Converter Power Switch ADIF equ 0x001 ; A/D Conversion Interupt Flag ADGO equ 0x002 ; A/D Conversion Start Flag CHS0 equ 0x003 ; A/D Converter Channel Select 0 CHS1 equ 0x004 ; A/D Converter Channel Select 1 ADCS0 equ 0x006 ; A/D Conversion Clock Select 0 ADCS1 equ 0x007 ; A/D Conversion Clock Select 0 ; ADCON1 Register (f88) Bits PCFG0 equ 0x000 ; RA0-RA3 Configuration Bit 0 PCFG1 equ 0x001 ; RA0-RA3 Configuration Bit 0 ; EECON1 Register (f88) Bits RD equ 0x000 ; PIC16C84 EEPROM Read Data Flag WR equ 0x001 ; PIC16C84 EEPROM Write Data Flag WREN equ 0x002 ; PIC16C84 EEPROM Write Enable Flag WRERR equ 0x003 ; PIC16C84 EEPROM Write Error Flag EEIF equ 0x004 ; PIC16C84 EEPROM Interupt Flag ; Some useful macros... PUSH macro movwf TEMP_W swapf STATUS,W movwf TEMP_S endm POP macro swapf TEMP_S,W movwf STATUS swapf TEMP_W swapf TEMP_W,W endm END ============================================================================== <End of PICREG.EQU>. The Security System: ~~~~~~~~~~~~~~~~~~~~ The security of the Schlumberger card system depends strongly on two things: the metal detector in the card reader which senses if there is any metal on the card where there shouldn't be any metal. Circuit traces on a home built card is definitively made of metal. So, we have to figure out a way of getting around this problem... Well, that isn't really too hard! They made one really big mistake: If the metal detector is grounded, it doesn't work!! If you look at the printout of my layouts for this card you'll find one big area of the board that is rectangle shaped. In this area you should make a big blob of solder that is between 2-3 millimetres high (approximately!). When the card slides into the phone, the blob should be touching the metal detector and since the blob is connected to ground the detector is also being grounded. The fone also counts the number of times the metal detector gets triggered by foreign objects in the card reader (Meaning that the phone companys security staff can see if someone's attempting to use a fake card that doesn't have this counter-measure on it!) and this is of course included in the daily service report the fone sends to the central computer. The second security lies in the cards first 12 bytes, it's not just what it appears to be: a serial number, it's more than that. Part of the first byte is a checksum of the number of 1's in the 11 bytes following it. Then byte 2 is always $83, identifying the card as an electronic phonecard. Byte 3 and 4 is the number of units on the card: The first nibble of byte 3 is always $1 and then in the remaining three nibbles the number of units is stored in BCD code, for example $11,$22 means 120 units (Two units is always fused at the factory as a test, see the text by Stephane Bausson!) Then we have 4 bytes of card serial number data, 2 bytes of card checksum (calculated with a 16 bit key stored in the payfone ROM), 1 byte that is always $11, and then at last, byte 12 which is the country identifier. The Parts Needed: ~~~~~~~~~~~~~~~~~ 01 * PIC16C84, 4 MHz version, Surface Mounted (SOIC-18 Package) 01 * 4 MHz Ceramic Resonator, Surface Mounted 02 * 22 pF Capacitors, Surface Mounted (Size 1206). 01 * 0.8mm thick singlesided circuit board with P20 photoresist The Construction: ~~~~~~~~~~~~~~~~~ Since this project is obviously not intended for the novice in electronics I will not go into the basic details of soldering/etching circuit boards. If you do not know much of this, ask a friend who does for help. If you want to reach me for help, write to Phrack and ask them to forward the letter to me as I wish to remain anonymous - This project will probably upset a lot of phone companies and last but not least the guys at Schlumberger Tech. The UUEncoded Part: ~~~~~~~~~~~~~~~~~~~ In this part of the phile you will find circuit board layouts for Tango PCB as well as HP Laserjet binary files which will output the layout when printed from DOS with the PRINT command. You will also find another version of the source code to use if your PIC prommer can't handle the programming of the 64 byte Data EEPROM array. <UUEncoded Part Begins Here>. ------------------------------------------------------------------------------ section 1 of uuencode 5.22 of file telecard.zip by R.E.M. begin 644 telecard.zip M4$L#!!0````(``Q2,!V^G@!LQ@@``.P@```,````5$5,14-21#$N05--Q5G= M<YLZ%G].9O(_G/1VM@_K9L%)D^YD^D`P2;GKV%[LW.P^=620;6TQ4!!QT[]^ M]8%``NQMLYU;SV0RH//3^=#Y%"?'1PM_,?8`X)4_G\+5>_L2YL])N,G3)"T+ MN,?;-'\&%^41>-LR1C3-7S'4V)\O&`AF'V:^:U^Z[R\&