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ST93C06 ST93C06C
256 bit (16 x 16 or 32 x 8) SERIAL MICROWIRE EEPROM
NOT FOR NEW DESIGN
1 MILLION ERASE/WRITE CYCLES, with 40 YEARS DATA RETENTION DUAL ORGANIZATION: 16 x 16 or 32 x 8 BYTE/WORD and ENTIRE MEMORY PROGRAMMING INSTRUCTIONS SELF-TIMED PROGRAMMING CYCLE with AUTO-ERASE READY/BUSY SIGNAL DURING PROGRAMMING SINGLE 5V 10% SUPPLY VOLTAGE SEQUENTIAL READ OPERATION 5ms TYPICAL PROGRAMMING TIME ENHANCED ESD/LATCH UP PERFORMANCES for "C" VERSION ST93C06 and ST93C06C are replaced by the M93C06 DESCRIPTION The ST93C06 and ST93C06C are 256 bit Electrically Erasable Programmable Memory (EEPROM) fabricated with SGS-THOMSON's High Endurance Single Polysilicon CMOS technology. In the text the two products are referred to as ST93C06. The memory is divided into either 32 x 8 bit bytes or 16 x 16 bit words. The organization may be selected by a signal applied on the ORG input. The memory is accessed through a serial input (D) and by a set of instructions which includes Read a byte/word, Write a byte/word, Erase a byte/word, Erase All and Write All. ARead instruction loads the address of the first byte/word to be read into an internal address pointer. Table 1. Signal Names
S D Q C ORG VCC VSS June 1997 Chip Select Input Serial Data Input Serial Data Output Serial Clock Organisation Select Supply Voltage Ground
8 1
PSDIP8 (B) 0.4mm Frame
8 1
SO8 (M) 150mil Width
Figure 1. Logic Diagram
VCC
D C S ORG ST93C06 ST93C06C
Q
VSS
AI00816B
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This is information on a product still in production bu t not recommended for new de signs.
ST93C06, ST93C06C
Figure 2A. DIP Pin Connections
Figure 2B. SO Pin Connections
ST93C06 ST93C06C S C D Q 1 2 3 4 8 7 6 5
AI00817B
ST93C06 ST93C06C VCC DU ORG VSS S C D Q 1 2 3 4 8 7 6 5
AI00818C
VCC DU ORG VSS
Warning: DU = Don't Use
Warning: DU = Don't Use
Table 2. Absolute Maximum Ratings (1)
Symbol TA TSTG TLEAD VIO VCC Parameter Ambient Operating Temperature Storage Temperature Lead Temperature, Soldering (SO8 package) (PSDIP8 package) 40 sec 10 sec Value -40 to 125 -65 to 150 215 260 -0.3 to VCC +0.5 -0.3 to 6.5
(2)
Unit C C C V V V V
Input or Output Voltages (Q = VOH or Hi-Z) Supply Voltage Electrostatic Discharge Voltage (Human Body model) ST93C06 ST93C06C ST93C06 ST93C06C
VESD Electrostatic Discharge Voltage (Machine model)
(3)
2000 4000 500 500
Notes: 1. Except for the rating "Operating Temperature Range", stresses above those listed in the Table "Absolute Maximum Ratings" may cause permanent damage to the device. These are stress ratings only and operation of the device at these or any other conditions above those indicated in the Operating sections of this specification is not implied. Exposure to Absolute Maximum Rating conditions for extended periods may affect device reliability. Refer also to the SGS-THOMSON SURE Program and other relevant quality documents. 2. MIL-STD-883C, 3015.7 (100pF, 1500 ). 3. EIAJ IC-121 (Condition C) (200pF, 0 ).
DESCRIPTION (cont'd) The data contained at this address is then clocked out serially. The address pointer is automatically incremented after the data is output and, if the Chip Select input (S) is held High, the ST93C06 can output a sequential stream of data bytes/words. In this way, the memory can be read as a data stream from 8 to 256 bits long, or continuously as the address counter automatically rolls over to '00' when the highest address is reached. Programming is internally self-timed (the external clock
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signal on C input may be disconnected or left running after the start of a Write cycle) and does not require an erase cycle prior to the Write instruction. The Write instruction writes 8 or 16 bits at one time into one of the 32 bytes or 16 words. After the start of the programming cycle aBusy/Ready signal is available on the Data output (Q) when Chip Select (S) is driven High. The design of the ST93C06 and the High Endurance CMOS technologyused for its fabrication give an Erase/Write cycle Endurance of 1,000,000 cycles and a data retention of 40 years.
ST93C06, ST93C06C
AC MEASUREMENT CONDITIONS
Input Rise and Fall Times Input Pulse Voltages Input Timing Reference Voltages Output Timing Reference Voltages 20ns 0.4V to 2.4V 1V to 2.0V 0.8V to 2.0V
Figure 3. AC Testing Input Output Waveforms
2.4V
2V 1V
2.0V 0.8V OUTPUT
AI00815
0.4V
Note that Output Hi-Z is defined as the point where data is no longer driven.
INPUT
Table 3. Capacitance (1) (TA = 25 C, f = 1 MHz )
Symbol C IN COUT Parameter Input Capacitance Output Capacitance Test Condition VIN = 0V VOUT = 0V Min Max 5 5 Unit pF pF
Note: 1. Sampled only, not 100% tested.
Table 4. DC Characteristics (TA = 0 to 70C or -40 to 85C; VCC = 5V 10%)
Symbol ILI ILO ICC Parameter Input Leakage Current Output Leakage Current Supply Current (TTL Inputs) Supply Current (CMOS Inputs) ICC1 VIL VIH VOL Supply Current (Standby) Input Low Voltage (D, C, S) Input High Voltage (D, C, S) Output Low Voltage IOL = 2.1mA IOL = 10 A IOH = -400A IOH = -10A 2.4 VCC - 0.2 Test Condition 0V VIN VCC 0V VOUT VCC, Q in Hi-Z S = VIH, f = 1 MHz S = VIH, f = 1 MHz S = VSS, C = VSS, ORG = VSS or VCC -0.3 2 Min Max 2.5 2.5 3 2 50 0.8 VCC + 1 0.4 0.2 Unit A A mA mA A V V V V V V
VOH
Output High Voltage
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ST93C06, ST93C06C
Table 5. AC Characteristics (TA = 0 to 70C or -40 to 85C; VCC = 5V 10%)
Symbol tSHCH tCLSH tDVCH tCHDX Alt tCSS tSKS tDIS tDIH Parameter Chip Select High to Clock High Clock Low to Chip Select High Input Valid to Clock High Temp. Range: grade 1 Clock High to Input Transition Temp. Range: grades 3, 6 Test Condition Min 50 100 100 100 200 500 500 0 250 Note 1 250 500 ST93C06 ST93C06C tCHCL tCLCH tW fC tSKH tSKL tWP fSK Clock High to Clock Low Clock Low to Clock High Erase/Write Cycle time Clock Frequency 0 Note 2 Note 2 250 250 10 1 300 200 Max Unit ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ms MHz
tCHQL tCHQV tCLSL tSLCH tSLSH tSHQV tSLQZ
tPD0 tPD1 tCSH
Clock High to Output Low Clock High to Output Valid Clock Low to Chip Select Low Chip Select Low to Clock High
tCS tSV tDF
Chip Select Low to Chip Select High Chip Select High to Output Valid Chip Select Low to Output Hi-Z
Notes: 1. Chip Select must be brought low for a minimum of 250 ns (tSLSH) between consecutive instruction cycles. 2. The Clock frequency specification calls for a minimum clock period of 1 s, therefore the sum of the timings tCHCL + tCLCH must be greater or equal to 1 s. For example, if tCHCL is 250 ns, then tCLCH must be at least 750 ns.
Figure 4. Synchronous Timing, Start and Op-Code Input
tCLSH C tSHCH S tDVCH D START OP CODE tCHCL
tCLCH
tCHDX OP CODE OP CODE OP CODE
START
OP CODE INPUT
AI00819C
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ST93C06, ST93C06C
Figure 5. Synchronous Timing, Read or Write
C tCLSL S tDVCH D An tCHQL Q15/Q7 tCHDX A0 tSLQZ Q0 tCHQV tSLSH
Hi-Z Q
ADDRESS INPUT
DATA OUTPUT
AI00820C
tSLCH C tCLSL S tDVCH D An tCHDX A0/D0 tSHQV Hi-Z Q BUSY tW ADDRESS/DATA INPUT WRITE CYCLE
AI01429
tSLSH
tSLQZ READY
DESCRIPTION (cont'd) The DU (Don't Use) pin does not affect the function of the memory and it is reserved for use by SGSTHOMSON during test sequences.The pin may be left unconnected or may be connected to VCC or VSS. Direct connection of DU to VSS is recommended for the lowest standby power consumption.
MEMORY ORGANIZATION The ST93C06 is organized as 32 bytes x 8 bits or 16 words x 16 bits. If the ORG input is left unconnected (or connected to VCC) the x16 organization is selected, when ORG is connected to Ground (VSS) the x8 organization is selected. When the ST93C06 is in standby mode, the ORG input should be unconnected or set to either VSS or VCC in order to achieve the minimum power consumption. Any voltage between VSS and VCC applied to ORG may increase the standby current value.
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ST93C06, ST93C06C
POWER-ON DATA PROTECTION In order to prevent data corruption and inadvertent write operations during power up, a Power On Reset (POR) circuit resets all internal programming circuitry and sets the device in the Write Disable mode. When VCC reaches its functional value, the device is properlyreset (in the Write Disable mode) and is ready to decode and execute an incoming instruction. A stable VCC must be applied before any logic signal. INSTRUCTIONS The ST93C06 has seven instructions, as shown in Table 6. The op-codes of the instructions are made up of 4 bits: some instructions use only the first two bits, others use all four bits to define the op-code. The op-code is followed by an address for the byte/word which is four bits long for the x16 organization or five bits long for the x8 organization. Each instruction is preceded by the rising edge of the signal applied on the S input (assuming that clock C and data input D are low), followed by a first clock pulse which is ignored by the ST93C06 (optional clock pulse for the ST93C06C). The data input D is then sampled upon the following rising edges of the clock C untill a '1' is sampled and decoded by the ST93C06 as a Start bit. Even though the first clock pulse is ignored, it recommended to pull low the data input D during this first clock pulse in order to keep the timing upwardly compatible with other ST93Cxx devices. The ST93C06 is fabricated in CMOS technology and is therefore able to run from zero Hz (static input signals) up to the maximum ratings (specified in Table 5). Read The Read instruction (READ) outputs serial data on the Data Output (Q). When a READ instruction is received, the instruction and address are decoded and the data from the memory is transferred into an output shiftregister. A dummy '0' bit is output first followed by the 8 bit byte or the 16 bit word with the MSB first. Output data changes are triggered by the Low to High transition of the Clock (C). The ST93C06 will automatically increment the address and will clock out the next byte/word as long as the Chip Select input (S) is held High. In this case the dummy '0' bit is NOT output between bytes/words and a continuous stream of data can be read. Erase/Write Enable and Disable The Erase/Write Enable instruction (EWEN) authorizesthe following Erase/Write instructions to be executed, the Erase/Write Disable instruction (EWDS) disables the execution of the following Erase/Write instructions. When power is first applied, the ST93C06 enters the Disable mode. When the Erase/Write Enable instruction (EWEN) is executed, Write instructions remain enabled until an Erase/Write Disable instruction (EWDS) is executed or if the Power-on reset circuit becomes active due to a reduced VCC. To protect the memory contents from accidental corruption, it is advisable to issue the EWDS instruction after every write cycle. The READ instruction is not affected by the EWEN or EWDS instructions. Erase The Erase instruction (ERASE) programs the addressed memory byte or word bits to '1'. Once the address is correctly decoded, the falling edge of the Chip Select input (S) triggers a self-timed erase cycle.
Table 6. Instruction Set
Instruction READ WRITE EWEN EWDS ERASE ERAL WRAL
Note: X = don't care bit.
Description Read Data from Memory Write Data to Memory Erase/Write Enable Erase/Write Disable Erase Byte or Word Erase All Memory Write All Memory with same Data
Op-Code 10XX 01XX 0011 0000 11XX 0010 0001
x8 Org Address (ORG = 0) A4-A0 A4-A0 XXXXX XXXXX A4-A0 XXXXX XXXXX
Data Q7-Q0 D7-D0
x16 Org Address (ORG = 1) A3-A0 A3-A0 XXXX XXXX A3-A0 XXXX
Data Q15-Q0 D15-D0
D7-D0
XXXX
D15-D0
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ST93C06, ST93C06C
Figure 6. READ, WRITE, EWEN, EWDS Sequences
READ
S
D
1 1 0 X X An A0
Q OP CODE ADDR
Qn DATA OUT
Q0
WRITE
S CHECK STATUS D 1 0 1 X X An A0 Dn D0
Q OP CODE ADDR DATA IN BUSY READY
ERASE WRITE ENABLE
S
ERASE WRITE DISABLE 1 0 0 1 1 Xn X0 OP CODE
S
D
D
1 0 0 0 0 Xn X0 OP CODE
AI00822D
Notes: 1. An: n = 3 for x16 org. and 4 for x8 org. 2. Xn: n = 3 for x16 org. and 4 for x8 org.
If the ST93C06 is still performing the erase cycle, the Busy signal (Q = 0) will be returned if S is driven high, and the ST93C06 will ignore any data on the bus. When the erase cycle is completed, the Ready signal (Q = 1) will indicate (if S is driven high) that the ST93C06 is ready to receive a new instruction. Write The Write instruction (WRITE) is followed by the address and the 8 or 16 data bits to be written. Data input is sampled on the Low to High transition of the clock. After the last data bit has been sampled, Chip Select (S) must be brought Low before the next rising edge of the clock (C) in order to start the
self-timed programming cycle. If the ST93C06 is still performing the write cycle, the Busy signal (Q = 0) will be returned if S is driven high, and the ST93C06 will ignore any data on the bus. When the write cycle is completed, the Ready signal (Q = 1) will indicate (if S is driven high) that the ST93C06 is ready to receive a new instruction. Programming is internally self-timed (the external clock signal on C input may be disconnected or left running after the start of a programming cycle) and does not require an Erase instruction prior to the Write instruction (The Write instruction includes an automatic erase cycle before programing data).
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ST93C06, ST93C06C
Figure 7. ERASE, ERAL Sequences
ERASE
S CHECK STATUS D 1 1 1 X X An A0
Q OP CODE ADDR BUSY READY
ERASE ALL
S CHECK STATUS D 1 0 0 1 0 Xn X0
Q OP CODE ADDR DUMMY BUSY READY
AI00823B
Notes: 1. An: n = 3 for x16 org. and 4 for x8 org. 2. Xn: n = 3 for x16 org. and 4 for x8 org.
Figure 8. WRAL Sequence
WRITE ALL
S CHECK STATUS D 1 0 0 0 1 Xn X0 Dn D0
Q OP CODE ADDR DUMMY DATA IN BUSY READY
AI00824B
Note: 1 Xn: n = 3 for x16 org. and 4 for x8 org.
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ST93C06, ST93C06C
Erase All The Erase All instruction (ERAL) erases the whole memory (all memory bits are set to '1'). A dummy address is input during the instruction transfer and the erase is made in the same way as the ERASE instruction. If the ST93C06 is still performing the erase cycle, the Busy signal (Q = 0) will be returned if S is driven high, and the ST93C06 will ignore any data on the bus. When the erase cycle is completed, the Ready signal (Q = 1) will indicate (if S is driven high) that the ST93C06 is ready to receive a new instruction. Write All For correct operation, an ERAL instruction should be executed before the WRAL instruction: the WRAL instruction DOES NOT perform an automatic erase before writing. The Write All instruction (WRAL) writes the Data Input byte or word to all the addresses of the memory. If the ST93C06 is still performing the write cycle, the Busy signal (Q = 0) will be returned if S is driven high, and the ST93C06 will ignore any data on the bus. When the write cycle is completed, the Ready signal (Q = 1) will indicate (if S is driven high) that the ST93C06 is ready to receive a new instruction. READY/BUSY Status During every programming cycle (after a WRITE, ERASE, WRAL or ERAL instruction) the Data Output (Q) indicates the Ready/Busy status of the memory when the Chip Select (S) is driven High. Once the ST93C06 is Ready, the Ready/Busy status is available on the Data Output (Q) until a new start bit is decoded or the Chip Select (S) is brought Low. COMMON I/O OPERATION The Data Output (Q) and Data Input (D) signals can be connected together, through a current limiting resistor, to form a common, one wire data bus. Some precautions must be taken when operating the memory with this connection, mostly to prevent a short circuit between the last entered address bit (A0) and the first data bit output by Q. The reader may also refer to the SGS-THOMSON application note "MICROWIRE EEPROM Common I/O Operation". DIFF ERENCES BETWEEN ST93C06 AND ST93C06C Each instruction of the ST93C06 requires an Additional Dummy clock pulse after the rising edge of the Chip Select input (S) and before the START bit, see Figure 9. When replacing the ST93C06 with the ST93C06C in an application, it must be checked that this Dummy Clock cycle DOES NOT HAPPEN when D = 1: if it is so, this clock pulse will latch an information which is decoded by the ST93C06C as a START bit (see Figure 10) and the following bits will be decoded with a shift of one bit.
Figure 9. ST93C06 Timing
S
D
C
0 Dummy Clock pulse
1 START Bit
AI01334
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ST93C06, ST93C06C
Figure 10. Comparative Timings
WRONG TIMING
S
D
C
1 Dummy Clock pulse START Bit
1 START Bit Bit = 1
For ST93C06: For ST93C06C:
GOOD TIMING
S
D
C
0 Dummy Clock pulse Nothing happens (waits for D = 1)
1 START Bit Bit = 1
AI01335
For ST93C06: For ST93C06C:
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ST93C06, ST93C06C
Figure 11. WRITE Swquence with One Clock Glitch
S
C
D
An START "0" WRITE "1"
An-1 Glitch
An-2 D0
ADDRESS AND DATA ARE SHIFTED BY ONE BIT
AI01395
DIFFERENCES BETWEEN ST93C06 AND ST93C06C (cont'd) The ST93C06C is an enhanced version of the ST93C06A and offers the following extra features: - Enhanced ESD voltage - Functional security filtering glitches on the clock input (C). Refer to Table 2 (Absolute Maximum Ratings) for more about ESD limits. The following description will detail the Clock pulses counter (available only on the ST93C06C). In a normal environment, the ST93C06 is expected to receive the exact amount of data on the D input, that is the exact amount of clock pulses on the C input. In a noisy environment, the amount of pulses received (on the clock input C) may be greater than the clock pulses delivered by the Master (Microcontroller) driving the ST93C06C. In such a case, a part of the instruction is delayed by one bit (see Figure 11), and it may induce an erroneous write of data at a wrong address.
The ST93C46C has an on-board counter which counts the clock pulses from the Start bit until the falling edge of the Chip Select signal. For the WRITE instructions, the number of clock pulses incoming to the counter must be exactly 18 (with the Organisation by 8) from the Start bit to the falling edge of Chip Select signal (1 Start bit + 2 bits of Op-code + 7 bits of Address + 8 bits of Data = 18): if so, the ST93C06C executes the WRITE instruction; if the number of clock pulses is not equal to 18, the instruction will not be executed (and data will not be corrupted). In the same way, when the Organisation by 16 is selected, the number of clock pulses incoming to the counter must be exactly 25 (1 Start bit + 2 bits of Op-code + 6 bits of Address + 16 bits of Data = 25) from the Start bit to the falling edge of Chip Select signal: if so, the ST93C06C executes the WRITE instruction; if the number of clock pulses is not equal to 25, the instruction will not be executed (and data will not be corrupted). The clock pulse counter is active only on ERASE and WRITE instructions (WRITE, ERASE, ERAL, WRALL).
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ST93C06, ST93C06C
ORDERING INFORMATION SCHEME Example: ST93C06C M 1 013TR
Revision blank CMOS F3 Tech. C CMOS F4 Tech.
Package B (1) PSDIP8 0.4mm Frame M SO8 150mil Width
Temperature Range 1 6 3
(2)
Option 013TR Tape & Reel Packing
0 to 70 C -40 to 85 C -40 to 125 C
Notes: 1. ST93C06CB1 is available with 0.25mm lead Frame only. 2. Temperature range on special request only.
Devices are shipped from the factory with the memory content set at all "1's" (FFFFh for x16, FFh for x8). For a list of available options (Package, etc...) or for further information on any aspect of this device, please contact the SGS-THOMSON Sales Office nearest to you.
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ST93C06, ST93C06C
PSDIP8 - 8 pin Plastic Skinny DIP, 0.4mm lead frame
Symb Typ A A1 A2 B B1 C D E E1 e1 eA eB L N
PSDIP8
mm Min Max 4.80 0.70 3.10 0.38 1.15 0.38 9.20 7.62 - 6.30 2.54 - 8.40 - 3.60 0.58 1.65 0.52 9.90 - 7.10 - - 9.20 3.00 8 3.80 0.100 0.300 Typ
inches Min Max 0.189 0.028 0.122 0.015 0.045 0.015 0.362 - 0.248 - 0.331 - 0.142 0.023 0.065 0.020 0.390 - 0.280 - - 0.362 0.118 8 0.150
A2 A1 B B1 D
N
A L eA eB C
e1
E1
1
E
PSDIP-a
Drawing is not to scale
13/15
ST93C06, ST93C06C
SO8 - 8 lead Plastic Small Outline, 150 mils body width
Symb Typ A A1 B C D E e H h L N CP
SO8
mm Min 1.35 0.10 0.33 0.19 4.80 3.80 1.27 - 5.80 0.25 0.40 0 8 0.10 Max 1.75 0.25 0.51 0.25 5.00 4.00 - 6.20 0.50 0.90 8 0.050 Typ
inches Min 0.053 0.004 0.013 0.007 0.189 0.150 - 0.228 0.010 0.016 0 8 0.004 Max 0.069 0.010 0.020 0.010 0.197 0.157 - 0.244 0.020 0.035 8
h x 45 A C B e D CP
N
E
1
H A1 L
SO-a
Drawing is not to scale
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ST93C06, ST93C06C
Information furnished is believed to be accurate and reliable. However, SGS-THOMSON Microelectronics assumes no responsibility for the consequences of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of SGS-THOMSON Microelectronics. Specifications mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied. SGS-THOMSON Microelectronics products are not authorized for use as critical components in life support devices or systems without express written approval of SGS-THOMSON Microelectronics. (c) 1997 SGS-THOMSON Microelectronics - All Rights Reserved (R) MICROWIRE is a registered trademark of National Semiconductor Corp. SGS-THOMSON Microelectronics GROUP OF COMPANIES Australia - Brazil - Canada - China - France - Germany - Hong Kong - Italy - Japan - Korea - Malaysia - Malta - Morocco - The Netherlands Singapore - Spain - Sweden - Switzerland - Taiwan - Thailand - United Kingdom - U.S.A.
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