19-4888; Rev 4; 1/12 1024-Bit EEPROM iButton The DS1972 is a 1024-bit, 1-Wire® EEPROM chip organized as four memory pages of 256 bits each in a rugged iButton® package. Data is written to an 8-byte scratchpad, verified, and then copied to the EEPROM memory. As a special feature, the four memory pages can individually be write protected or put in EPROMemulation mode, where bits can only be changed from a 1 to a 0 state. The DS1972 communicates over the single-conductor 1-Wire bus. The communication follows the standard 1-Wire protocol. Each device has its own unalterable and unique 64-bit ROM registration number that is factory lasered into the device. The registration number is used to address the device in a multidrop, 1-Wire net environment. Applications Access Control/Parking Meter Work-in-Progress Tracking Examples of Accessories Self-Stick Adhesive Pad DS9101 Multipurpose Clip DS9093RA Mounting Lock Ring DS9093A Snap-In Fob DS9092 iButton Probe ♦ Communicates to Host with a Single Digital Signal at 15.4kbps or 125kbps Using 1-Wire Protocol ♦ Built-In Multidrop Controller for 1-Wire Net ♦ Easily Affixed with Self-Stick Adhesive Backing, Latched by its Flange, or Locked with a Ring Pressed Onto its Rim ♦ Presence Detector Acknowledges When Reader First Applies Voltage 5.89mm 0.51mm ut 52 Ordering Information t o n ®. c om iB BRANDING 16.25mm ® 2D 0000006234FB 5 1-Wire® 2 WZ ZZ D S197 -F YY W IO ♦ Reads and Writes Over a Wide Voltage Range from 2.8V to 5.25V from -40°C to +85°C ♦ Button Shape is Self-Aligning with Cup-Shaped Probes F5 SIZE 0.51mm ♦ IEC 1000-4-2 Level 4 ESD Protection (±8kV Contact, ±15kV Air, Typical) ♦ Data Can Be Accessed While Affixed to Object Pin Configurations 3.10mm ♦ Switchpoint Hysteresis and Filtering to Optimize Performance in the Presence of Noise ♦ Chip-Based Data Carrier Stores Digital Identification and Information, Armored in a Durable Stainless-Steel Case ACCESSORY F3 SIZE ♦ Individual Memory Pages Can Be Permanently Write Protected or Put in EPROM-Emulation Mode (“Write to 0”) ♦ Unique Factory-Lasered 64-Bit Registration Number Ensures Error-Free Device Selection and Absolute Traceability Because No Two Parts are Alike Maintenance/Inspection Data Storage DS9096P ♦ 1024 Bits of EEPROM Memory Partitioned Into Four Pages of 256 Bits Common iButton Features Tool Management Inventory Control PART Features PART TEMP RANGE PIN-PACKAGE DS1972-F5+ -40°C to +85°C F5 iButton DS1972-F3+ -40°C to +85°C F3 iButton +Denotes a lead(Pb)-free/RoHS-compliant package. 17.35mm IO GND GND 1-Wire and iButton are registered trademarks of Maxim Integrated Products, Inc. ________________________________________________________________ Maxim Integrated Products For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com. 1 DS1972 General Description DS1972 1024-Bit EEPROM iButton ABSOLUTE MAXIMUM RATINGS IO Voltage Range to GND .......................................-0.5V to +6V IO Sink Current ...................................................................20mA Operating Temperature Range ...........................-40°C to +85°C Junction Temperature ......................................................+150°C Storage Temperature Range .............................-55°C to +125°C Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. ELECTRICAL CHARACTERISTICS (TA = -40°C to +85°C, unless otherwise noted.) (Note 1) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS IO PIN: GENERAL DATA 1-Wire Pullup Voltage VPUP (Note 2) 2.8 5.25 V 1-Wire Pullup Resistance RPUP (Notes 2, 3) 0.3 2.2 k Input Capacitance CIO (Notes 4, 5) 1000 pF Input Load Current IL 0.05 6.7 μA 0.5 VPUP 1.8 V 0.5 V IO pin at VPUP High-to-Low Switching Threshold VTL (Notes 5, 6, 7) Input Low Voltage VIL (Notes 2, 8) Low-to-High Switching Threshold VTH (Notes 5, 6, 9) 1.0 VPUP 1.0 V Switching Hysteresis VHY (Notes 5, 6, 10) 0.21 1.70 V Output Low Voltage VOL At 4mA (Note 11) 0.4 V Recovery Time (Notes 2, 12) tREC Rising-Edge Hold-Off Time (Notes 5, 13) tREH Time Slot Duration (Notes 2, 14) t SLOT Standard speed, RPUP = 2.2k 5 Overdrive speed, RPUP = 2.2k 2 Overdrive speed, directly prior to reset pulse; RPUP = 2.2k 5 Standard speed Overdrive speed 0.5 μs 5.0 Not applicable (0) Standard speed 65 Overdrive speed 8 μs μs IO PIN: 1-Wire RESET, PRESENCE-DETECT CYCLE Reset Low Time (Note 2) tRSTL Presence-Detect High Time t PDH Presence-Detect Low Time t PDL Presence-Detect Sample Time (Notes 2, 15) tMSP 2 Standard speed 480 640 Overdrive speed 48 80 Standard speed 15 60 Overdrive speed 2 6 Standard speed 60 240 Overdrive speed 8 24 Standard speed 60 75 Overdrive speed 6 10 _______________________________________________________________________________________ μs μs μs μs 1024-Bit EEPROM iButton (TA = -40°C to +85°C, unless otherwise noted.) (Note 1) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS IO PIN: 1-Wire WRITE Write-Zero Low Time (Notes 2, 16, 17) Write-One Low Time (Notes 2, 17) tW0L tW1L Standard speed 60 120 Overdrive speed, VPUP > 4.5V 5 15.5 Overdrive speed 6 15.5 Standard speed 1 15 Overdrive speed 1 2 Standard speed 5 15 - Overdrive speed 1 2- Standard speed tRL + 15 Overdrive speed tRL + 2 μs μs IO PIN: 1-Wire READ Read Low Time (Notes 2, 18) tRL Read Sample Time (Notes 2, 18) tMSR μs μs EEPROM Programming Current I PROG (Notes 5, 19) 0.8 mA Programming Time t PROG (Note 20) 10 ms Write/Erase Cycles (Endurance) (Notes 21, 22) NCY Data Retention (Notes 23, 24, 25) tDR Note 1: Note 2: Note 3: Note 4: Note 5: Note 6: Note 7: Note 8: Note 9: Note 10: Note 11: Note 12: Note 13: Note 14: Note 15: Note 16: Note 17: Note 18: At +25°C 200k At +85°C (worst case) 50k At +85°C (worst case) 40 Years Limits are 100% production tested at TA = +25°C and/or TA = +85°C. Limits over the operating temperature range and relevant supply voltage range are guaranteed by design and characterization. Typical values are not guaranteed. System requirement. Maximum allowable pullup resistance is a function of the number of 1-Wire devices in the system and 1-Wire recovery times. The specified value here applies to systems with only one device and with the minimum 1-Wire recovery times. For more heavily loaded systems, an active pullup such as that found in the DS2482-x00, DS2480B, or DS2490 may be required. Maximum value represents the internal parasite capacitance when VPUP is first applied. If a 2.2kΩ resistor is used to pull up the data line, 2.5µs after VPUP has been applied, the parasite capacitance does not affect normal communications. Guaranteed by design, characterization, and/or simulation only. Not production tested. VTL, VTH, and VHY are a function of the internal supply voltage, which is a function of VPUP, RPUP, 1-Wire timing, and capacitive loading on IO. Lower VPUP, higher RPUP, shorter tREC, and heavier capacitive loading all lead to lower values of VTL, VTH, and VHY. Voltage below which, during a falling edge on IO, a logic 0 is detected. The voltage on IO must be less than or equal to VILMAX at all times the master is driving IO to a logic 0 level. Voltage above which, during a rising edge on IO, a logic 1 is detected. After VTH is crossed during a rising edge on IO, the voltage on IO must drop by at least VHY to be detected as logic 0. The I-V characteristic is linear for voltages less than 1V. Applies to a single device attached to a 1-Wire line. The earliest recognition of a negative edge is possible at tREH after VTH has been reached on the preceding rising edge. Defines maximum possible bit rate. Equal to tW0LMIN + tRECMIN. Interval after tRSTL during which a bus master is guaranteed to sample a logic 0 on IO if there is a DS1972 present. Minimum limit is tPDHMAX; maximum limit is tPDHMIN + tPDLMIN. Numbers in bold are not in compliance with legacy 1-Wire product standards. See the Comparison Table. ε in Figure 11 represents the time required for the pullup circuitry to pull the voltage on IO up from VIL to VTH. The actual maximum duration for the master to pull the line low is tW1LMAX + tF - ε and tW0LMAX + tF - ε, respectively. δ in Figure 11 represents the time required for the pullup circuitry to pull the voltage on IO up from VIL to the input-high threshold of the bus master. The actual maximum duration for the master to pull the line low is tRLMAX + tF. _______________________________________________________________________________________ 3 DS1972 ELECTRICAL CHARACTERISTICS (continued) DS1972 1024-Bit EEPROM iButton Note 19: Current drawn from IO during the EEPROM programming interval. The pullup circuit on IO during the programming interval should be such that the voltage at IO is greater than or equal to VPUPMIN. If VPUP in the system is close to VPUPMIN, a lowimpedance bypass of RPUP, which can be activated during programming, may need to be added. Note 20: Interval begins tREHMAX after the trailing rising edge on IO for the last time slot of the E/S byte for a valid Copy Scratchpad sequence. Interval ends once the device’s self-timed EEPROM programming cycle is complete and the current drawn by the device has returned from IPROG to IL. Note 21: Write-cycle endurance is degraded as TA increases. Note 22: Not 100% production tested; guaranteed by reliability monitor sampling. Note 23: Data retention is degraded as TA increases. Note 24: Guaranteed by 100% production test at elevated temperature for a shorter time; equivalence of this production test to the data sheet limit at operating temperature range is established by reliability testing. Note 25: EEPROM writes can become nonfunctional after the data-retention time is exceeded. Long-term storage at elevated temperatures is not recommended; the device can lose its write capability after 10 years at +125°C or 40 years at +85°C. COMPARISON TABLE LEGACY VALUES PARAMETER t SLOT (including tREC) STANDARD SPEED (μs) MIN MAX DS1972 VALUES OVERDRIVE SPEED (μs) MIN MAX STANDARD SPEED (μs) MIN MAX OVERDRIVE SPEED (μs) MIN MAX 61 (undefined) 7 (undefined) 65* (undefined) 8* (undefined) tRSTL 480 (undefined) 48 80 480 640 48 80 t PDH 15 60 2 6 15 60 2 6 t PDL 60 240 8 24 60 240 8 24 tW0L 60 120 6 16 60 120 6 15.5 *Intentional change; longer recovery time requirement due to modified 1-Wire front-end. Note: Numbers in bold are not in compliance with legacy 1-Wire product standards. 4 _______________________________________________________________________________________ 1024-Bit EEPROM iButton The DS1972 combines 1024 bits of EEPROM, an 8-byte register/control page with up to 7 user read/write bytes, and a fully featured 1-Wire interface in a rugged iButton package. Each DS1972 has its own 64-bit ROM registration number that is factory lasered into the chip to provide a guaranteed unique identity for absolute traceability. Data is transferred serially through the 1Wire protocol, which requires only a single data contact and a ground return. The DS1972 has an additional memory area called the scratchpad that acts as a buffer when writing to the main memory or the register page. Data is first written to the scratchpad from which it can be read back. After the data has been verified, a Copy Scratchpad command transfers the data to its final memory location. Applications of the DS1972 include access control/parking meter, work-in-progress tracking, tool management, inventory control, and maintenance/inspection data storage. Free software for communication with the DS1972 is available at www.maxim-ic.com/ibutton. PARASITE POWER IO DS1972 COMMAND LEVEL: 1-Wire ROM FUNCTION COMMANDS (SEE FIGURE 9) DS1972-SPECIFIC MEMORY FUNCTION COMMANDS (SEE FIGURE 7) 1-Wire FUNCTION CONTROL 64-BIT LASERED ROM DS1972 MEMORY FUNCTION CONTROL UNIT CRC-16 GENERATOR DATA MEMORY 4 PAGES OF 256 BITS EACH Overview The block diagram in Figure 1 shows the relationships between the major control and memory sections of the DS1972. The DS1972 has four main data components: 64-bit lasered ROM, 64-bit scratchpad, four 32-byte pages of EEPROM, and a 64-bit register page. The hierarchical structure of the 1-Wire protocol is shown in Figure 2. The bus master must first provide one of the seven ROM function commands: Read ROM, Match ROM, Search ROM, Skip ROM, Resume, Overdrive-Skip ROM, or Overdrive-Match ROM. Upon DS1972 Detailed Description 64-BIT SCRATCHPAD REGISTER PAGE 64 BITS Figure 1. Block Diagram completion of an Overdrive-Skip ROM or OverdriveMatch ROM command byte executed at standard speed, the device enters overdrive mode where all subsequent communication occurs at a higher speed. The protocol required for these ROM function AVAILABLE COMMANDS: DATA FIELD AFFECTED: READ ROM MATCH ROM SEARCH ROM SKIP ROM RESUME OVERDRIVE-SKIP ROM OVERDRIVE-MATCH ROM 64-BIT REG. #, RC-FLAG 64-BIT REG. #, RC-FLAG 64-BIT REG. #, RC-FLAG RC-FLAG RC-FLAG RC-FLAG, OD-FLAG 64-BIT REG. #, RC-FLAG, OD-FLAG WRITE SCRATCHPAD READ SCRATCHPAD COPY SCRATCHPAD READ MEMORY 64-BIT SCRATCHPAD, FLAGS 64-BIT SCRATCHPAD DATA MEMORY, REGISTER PAGE DATA MEMORY, REGISTER PAGE Figure 2. Hierarchical Structure for 1-Wire Protocol _______________________________________________________________________________________ 5 DS1972 1024-Bit EEPROM iButton MSB LSB 8-BIT CRC CODE MSB 8-BIT FAMILY CODE (2Dh) 48-BIT SERIAL NUMBER LSB MSB LSB MSB LSB Figure 3. 64-Bit Lasered ROM POLYNOMIAL = X8 + X5 + X4 + 1 1ST STAGE X0 2ND STAGE X1 3RD STAGE X2 4TH STAGE X3 5TH STAGE X4 6TH STAGE X5 7TH STAGE X6 8TH STAGE X7 X8 INPUT DATA Figure 4. 1-Wire CRC Generator commands is described in Figure 9. After a ROM function command is successfully executed, the memory functions become accessible and the master can provide any one of the four memory function commands. The protocol for these memory function commands is described in Figure 7. All data is read and written least significant bit first. 64-Bit Lasered ROM Each DS1972 contains a unique ROM code that is 64 bits long. The first 8 bits are a 1-Wire family code. The next 48 bits are a unique serial number. The last 8 bits are a cyclic redundancy check (CRC) of the first 56 bits. See Figure 3 for details. The 1-Wire CRC is generated 6 using a polynomial generator consisting of a shift register and XOR gates as shown in Figure 4. The polynomial is X8 + X5 + X4 + 1. Additional information about the 1-Wire CRC is available in Application Note 27: Understanding and Using Cyclic Redundancy Checks with Maxim iButton Products. The shift register bits are initialized to 0. Then, starting with the least significant bit of the family code, one bit at a time is shifted in. After the 8th bit of the family code has been entered, the serial number is entered. After the last bit of the serial number has been entered, the shift register contains the CRC value. Shifting in the 8 bits of the CRC returns the shift register to all 0s. _______________________________________________________________________________________ 1024-Bit EEPROM iButton Data memory and registers are located in a linear address space, as shown in Figure 5. The data memory and the registers have unrestricted read access. The DS1972 EEPROM array consists of 18 rows of 8 bytes each. The first 16 rows are divided equally into four memory pages (32 bytes each). These four pages are the primary data memory. Each page can be individually set to open (unprotected), write protected, or EPROM mode by setting the associated protection byte in the register row. As a factory default, the entire data memory is unprotected and its contents are undefined. The last two rows contain protection registers and reserved bytes. The register row consists of 4 protection-control bytes, a copy-protection byte, the factory byte, and 2 user byte/manufacture ID bytes. The manufacturer ID can be a customer-supplied identification code that assists the application software in identifying the product with which the DS1972 is associated. Contact the factory to set up and register a custom manufacturer ID. The last row is reserved for future use. It is undefined in terms of R/W functionality and should not be used. In addition to the main EEPROM array, an 8-byte volatile scratchpad is included. Writes to the EEPROM array are a two-step process. First, data is written to the scratchpad and then copied into the main array. This allows the user to first verify the data written to the scratchpad prior to copying into the main array. The device only supports full row (8-byte) copy operations. For data in the scratchpad to be valid for a copy operation, the address supplied with a Write Scratchpad command must start on a row boundary, and 8 full bytes must be written into the scratchpad. ADDRESS RANGE TYPE 0000h to 001Fh R/(W) Data Memory Page 0 DESCRIPTION — PROTECTION CODES 0020h to 003Fh R/(W) Data Memory Page 1 — 0040h to 005Fh R/(W) Data Memory Page 2 — 0060h to 007Fh R/(W) Data Memory Page 3 — 0080h* R/(W) Protection-Control Byte Page 0 55h: Write Protect P0; AAh: EPROM Mode P0; 55h or AAh: Write Protect 80h 0081h* R/(W) Protection-Control Byte Page 1 55h: Write Protect P1; AAh: EPROM Mode P1; 55h or AAh: Write Protect 81h 0082h* R/(W) Protection-Control Byte Page 2 55h: Write Protect P2; AAh: EPROM Mode P2; 55h or AAh: Write Protect 82h 0083h* R/(W) Protection-Control Byte Page 3 55h: Write Protect P3; AAh: EPROM Mode P3; 55h or AAh: Write Protect 83h 0084h* R/(W) Copy Protection Byte 55h or AAh: Copy Protect 0080h:008Fh, and Any Write-Protected Pages 0085h R Factory Byte. Set at Factory. AAh: Write Protect 85h, 86h, 87h; 55h: Write Protect 85h; Unprotect 86h, 87h 0086h R/(W) User Byte/Manufacturer ID — 0087h R/(W) User Byte/Manufacturer ID — 0088h to 008Fh — Reserved — *Once programmed to AAh or 55h this address becomes read only. All other codes can be stored, but neither write protect the address nor activate any function. Figure 5. Memory Map _______________________________________________________________________________________ 7 DS1972 Memory Access DS1972 1024-Bit EEPROM iButton The protection-control registers determine how incoming data on a Write Scratchpad command is loaded into the scratchpad. A protection setting of 55h (write protect) causes the incoming data to be ignored and the target address main memory data to be loaded into the scratchpad. A protection setting of AAh (EPROM mode) causes the logical AND of incoming data and target address main memory data to be loaded into the scratchpad. Any other protection-control register setting leaves the associated memory page open for unrestricted write access. Note: For the EPROM mode to function, the entire affected memory page must first be programmed to FFh. Protection-control byte settings of 55h or AAh also write protect the protection-control byte. The protection-control byte setting of 55h does not block the copy. This allows write-protected data to be refreshed (i.e., reprogrammed with the current data) in the device. The copy-protection byte is used for a higher level of security and should only be used after all other protection-control bytes, user bytes, and write-protected pages are set to their final value. If the copy-protection byte is set to 55h or AAh, all copy attempts to the register row and user-byte row are blocked. In addition, all copy attempts to write-protected main memory pages (i.e., refresh) are blocked. Address Registers and Transfer Status The DS1972 employs three address registers: TA1, TA2, and E/S (Figure 6). These registers are common to many other 1-Wire devices but operate slightly differently with the DS1972. Registers TA1 and TA2 must be loaded with the target address to which the data is written or from which data is read. Register E/S is a read-only transferstatus register used to verify data integrity with write commands. E/S bits E[2:0] are loaded with the incoming T[2:0] on a Write Scratchpad command and increment on each subsequent data byte. This is, in effect, a byteending offset counter within the 8-byte scratchpad. Bit 5 of the E/S register, called PF, is a logic 1 if the data in the scratchpad is not valid due to a loss of power or if the master sends fewer bytes than needed to reach the end of the scratchpad. For a valid write to the scratchpad, T[2:0] must be 0 and the master must have sent 8 data bytes. Bits 3, 4, and 6 have no function; they always read 0. The highest valued bit of the E/S register, called authorization accepted (AA), acts as a flag to indicate that the data stored in the scratchpad has already been copied to the target memory address. Writing data to the scratchpad clears this flag. Writing with Verification To write data to the DS1972, the scratchpad must be used as intermediate storage. First, the master issues the Write Scratchpad command to specify the desired target address, followed by the data to be written to the scratchpad. Note that Copy Scratchpad commands must be performed on 8-byte boundaries, i.e., the three LSBs of the target address (T2, T1, T0) must be equal to 000b. If T[2:0] are sent with nonzero values, the copy function is blocked. Under certain conditions (see the Write Scratchpad [0Fh] section) the master receives an BIT # 7 6 5 4 3 2 1 0 TARGET ADDRESS (TA1) T7 T6 T5 T4 T3 T2 T1 T0 TARGET ADDRESS (TA2) T15 T14 T13 T12 T11 T10 T9 T8 ENDING ADDRESS WITH DATA STATUS (E/S) (READ ONLY) AA 0 PF 0 0 E2 E1 E0 Figure 6. Address Registers 8 _______________________________________________________________________________________ 1024-Bit EEPROM iButton Memory Function Commands The Memory Function Flowchart (Figure 7) describes the protocols necessary for accessing the memory of the DS1972. An example on how to use these functions to write to and read from the device is in the Memory Function Example section. The communication between the master and the DS1972 takes place either at standard speed (default, OD = 0) or at overdrive speed (OD = 1). If not explicitly set into overdrive mode, the DS1972 assumes standard speed. Write Scratchpad [0Fh] The Write Scratchpad command applies to the data memory and the writable addresses in the register page. For the scratchpad data to be valid for copying to the array, the user must perform a Write Scratchpad command of 8 bytes starting at a valid row boundary. The Write Scratchpad command accepts invalid addresses and partial rows, but subsequent Copy Scratchpad commands are blocked. After issuing the Write Scratchpad command, the master must first provide the 2-byte target address, followed by the data to be written to the scratchpad. The data is written to the scratchpad starting at the byte offset of T[2:0]. The E/S bits E[2:0] are loaded with the starting byte offset and increment with each subsequent byte. Effectively, E[2:0] is the byte offset of the last full byte written to the scratchpad. Only full data bytes are accepted. When executing the Write Scratchpad command, the CRC generator inside the DS1972 (Figure 13) calculates a CRC of the entire data stream, starting at the command code and ending at the last data byte as sent by the master. This CRC is generated using the CRC-16 polynomial by first clearing the CRC generator and then shifting in the command code (0Fh) of the Write Scratchpad command, the target addresses (TA1 and TA2), and all the data bytes. Note that the CRC-16 calculation is performed with the actual TA1 and TA2 and data sent by the master. The master can end the Write Scratchpad command at any time. However, if the end of the scratchpad is reached (E[2:0] = 111b), the master can send 16 read time slots and receive the CRC generated by the DS1972. If a Write Scratchpad command is attempted to a writeprotected location, the scratchpad is loaded with the data already existing in memory rather than the data transmitted. Similarly, if the target address page is in EPROM mode, the scratchpad is loaded with the bitwise logical AND of the transmitted data and data already existing in memory. Read Scratchpad [AAh] The Read Scratchpad command allows verifying the target address and the integrity of the scratchpad data. After issuing the command code, the master begins reading. The first 2 bytes are the target address. The next byte is the ending offset/data status byte (E/S) followed by the scratchpad data, which may be different from what the master originally sent. This is of particular importance if the target address is within the register page or a page in either write-protection mode or EPROM mode. See the Write Scratchpad [0Fh] section for details. The master should read through the scratchpad (E[2:0] - T[2:0] + 1 bytes), after which it receives the inverted CRC based on data as it was sent by the DS1972. If the master continues reading after the CRC, all data is logic 1. _______________________________________________________________________________________ 9 DS1972 inverted CRC-16 of the command, address (actual address sent), and data at the end of the Write Scratchpad command sequence. Knowing this CRC value, the master can compare it to the value it has calculated to decide if the communication was successful and proceed to the Copy Scratchpad command. If the master could not receive the CRC-16, it should send the Read Scratchpad command to verify data integrity. As a preamble to the scratchpad data, the DS1972 repeats the target address TA1 and TA2 and sends the contents of the E/S register. If the PF flag is set, data did not arrive correctly in the scratchpad, or there was a loss of power since data was last written to the scratchpad. The master does not need to continue reading; it can start a new trial to write data to the scratchpad. Similarly, a set AA flag together with a cleared PF flag indicate that the device did not recognize the Write Scratchpad command. If everything went correctly, both flags are cleared. Now the master can continue reading and verifying every data byte. After the master has verified the data, it can send the Copy Scratchpad command, for example. This command must be followed exactly by the data of the three address registers: TA1, TA2, and E/S. The master should obtain the contents of these registers by reading the scratchpad. DS1972 1024-Bit EEPROM iButton FROM ROM FUNCTIONS FLOWCHART (FIGURE 9) BUS MASTER Tx MEMORY FUNCTION COMMAND 0Fh WRITE SCRATCHPAD? AAh READ SCRATCHPAD? N Y Y BUS MASTER Tx TA1 (T[7:0]), TA2 (T[15:8]) BUS MASTER Rx TA1 (T[7:0]), TA2 (T[15:8]), AND E/S BYTE DS1972 SETS PF = 1 CLEARS AA = 0 SETS E[2:0] = T[2:0] DS1972 SETS SCRATCHPAD BYTE COUNTER = T[2:0] MASTER Tx DATA BYTE TO SCRATCHPAD DS1972 INCREMENTS E[2:0] MASTER Tx RESET? APPLIES ONLY IF THE MEMORY AREA IS NOT PROTECTED. Y N N Y BUS MASTER Rx DATA BYTE FROM SCRATCHPAD DS1972 INCREMENTS BYTE COUNTER IF WRITE PROTECTED, THE DS1972 COPIES THE DATE BYTE FROM THE TARGET ADDRESS INTO THE SCRATCHPAD. IF IN EPROM MODE, THE DS1972 LOADS THE BITWISE LOGICAL AND OF THE TRANSMITTED BYTE AND THE DATA BYTE FROM THE TARGETED ADDRESS INTO THE SCRATCHPAD. E[2:0] = 7? T[2:0] = 0? TO FIGURE 7b N MASTER Tx RESET? Y N N BYTE COUNTER = E[2:0]? Y N BUS MASTER Rx CRC-16 OF COMMAND, ADDRESS, E/S BYTE, AND DATA BYTES AS SENT BY THE DS1972 Y PF = 0 BUS MASTER Rx "1"s DS1972 Tx CRC-16 OF COMMAND, ADDRESS, AND DATA BYTES AS THEY WERE SENT BY THE BUS MASTER BUS MASTER Rx "1"s N N MASTER Tx RESET? Y MASTER Tx RESET? Y FROM FIGURE 7b TO ROM FUNCTIONS FLOWCHART (FIGURE 9) Figure 7a. Memory Function Flowchart 10 ______________________________________________________________________________________ 1024-Bit EEPROM iButton 55h COPY SCRATCHPAD? Y Y BUS MASTER Tx TA1 (T[7:0]), TA2 (T[15:8]) ADDRESS < 90h? Y T[15:0] < 0090h? N Y APPLICABLE TO ALL R/W MEMORY LOCATIONS. BUS MASTER Tx TA1 (T[7:0]), TA2 (T[15:8]) AND E/S BYTE AUTH. CODE MATCH? F0h READ MEMORY? N DS1972 FROM FIGURE 7a Y N N DS1972 SETS MEMORY ADDRESS = (T[15:0]) N N PF = 0? Y BUS MASTER Rx DATA BYTE FROM MEMORY ADDRESS DS1972 INCREMENTS ADDRESS COUNTER Y COPY PROTECTED? MASTER Tx RESET? Y BUS MASTER Rx "1"s N N AA = 1 N Y DURATION: tPROG DS1972 COPIES SCRATCHPAD DATA TO ADDRESS BUS MASTER Rx "1"s MASTER Tx RESET? ADDRESS < 8Fh? * Y N DS1972 Tx "0" BUS MASTER Rx "1"s N MASTER Tx RESET? Y MASTER Tx RESET? N Y MASTER Tx RESET? Y N DS1972 Tx "1" MASTER Tx RESET? N Y TO FIGURE 7a * 1-Wire IDLE HIGH FOR POWER. Figure 7b. Memory Function Flowchart (continued) ______________________________________________________________________________________ 11 DS1972 1024-Bit EEPROM iButton Copy Scratchpad [55h] The Copy Scratchpad command is used to copy data from the scratchpad to writable memory sections. After issuing the Copy Scratchpad command, the master must provide a 3-byte authorization pattern, which should have been obtained by an immediately preceding Read Scratchpad command. This 3-byte pattern must exactly match the data contained in the three address registers (TA1, TA2, E/S, in that order). If the pattern matches, the target address is valid, the PF flag is not set, and the target memory is not copy protected, then the AA flag is set and the copy begins. All 8 bytes of scratchpad contents are copied to the target memory location. The duration of the device’s internal data transfer is tPROG during which the voltage on the 1-Wire bus must not fall below 2.8V. A pattern of alternating 0s and 1s are transmitted after the data has been copied until the master issues a reset pulse. If the PF flag is set or the target memory is copy protected, the copy does not begin and the AA flag is not set. If the copy command was disturbed due to lack of power or for other reasons, the master will read a constant stream of FFh bytes until it sends a 1-Wire Reset Pulse. In this case, the destination memory may be incompletely programmed requiring a Write Scratchpad command and Copy Scratchpad command be repeated to ensure proper programming of the EEPROM. This requires careful consideration when designing application software that writes to the DS1972 in an intermittent contact environment. Read Memory [F0h] The Read Memory command is the general function to read data from the DS1972. After issuing the command, the master must provide the 2-byte target address. After these 2 bytes, the master reads data beginning from the target address and can continue until address 008Fh. If the master continues reading, the result is logic 1s. The device’s internal TA1, TA2, E/S, and scratchpad contents are not affected by a Read Memory command. 1-Wire Bus System The 1-Wire bus is a system that has a single bus master and one or more slaves. In all instances the DS1972 is a slave device. The bus master is typically a microcontroller. The discussion of this bus system is broken 12 down into three topics: hardware configuration, transaction sequence, and 1-Wire signaling (signal types and timing). The 1-Wire protocol defines bus transactions in terms of the bus state during specific time slots, which are initiated on the falling edge of sync pulses from the bus master. Hardware Configuration The 1-Wire bus has only a single line by definition; it is important that each device on the bus be able to drive it at the appropriate time. To facilitate this, each device attached to the 1-Wire bus must have open-drain or three-state outputs. The 1-Wire port of the DS1972 is open drain with an internal circuit equivalent to that shown in Figure 8. A multidrop bus consists of a 1-Wire bus with multiple slaves attached. The DS1972 supports both a standard and overdrive communication speed of 15.4kbps (max) and 125kbps (max), respectively. Note that legacy 1-Wire products support a standard communication speed of 16.3kbps and overdrive of 142kbps. The slightly reduced rates for the DS1972 are a result of additional recovery times, which in turn were driven by a 1-Wire physical interface enhancement to improve noise immunity. The value of the pullup resistor primarily depends on the network size and load conditions. The DS1972 requires a pullup resistor of 2.2kΩ (max) at any speed. The idle state for the 1-Wire bus is high. If for any reason a transaction needs to be suspended, the bus must be left in the idle state if the transaction is to resume. If this does not occur and the bus is left low for more than 16µs (overdrive speed) or more than 120µs (standard speed), one or more devices on the bus could be reset. Transaction Sequence The protocol for accessing the DS1972 through the 1-Wire port is as follows: • • • • Initialization ROM Function Command Memory Function Command Transaction/Data ______________________________________________________________________________________ 1024-Bit EEPROM iButton DS1972 VPUP BUS MASTER DS1972 1-Wire PORT RPUP DATA Rx Tx Rx = RECEIVE Tx = TRANSMIT OPEN-DRAIN PORT PIN Rx IL Tx 100Ω MOSFET Figure 8. Hardware Configuration Initialization All transactions on the 1-Wire bus begin with an initialization sequence. The initialization sequence consists of a reset pulse transmitted by the bus master followed by presence pulse(s) transmitted by the slave(s). The presence pulse lets the bus master know that the DS1972 is on the bus and is ready to operate. For more details, see the 1-Wire Signaling section. 1-Wire ROM Function Commands Once the bus master has detected a presence, it can issue one of the seven ROM function commands the DS1972 supports. All ROM function commands are 8 bits long. A list of these commands follows (see the flowchart in Figure 9). Read ROM [33h] The Read ROM command allows the bus master to read the DS1972’s 8-bit family code, unique 48-bit serial number, and 8-bit CRC. This command can only be used if there is a single slave on the bus. If more than one slave is present on the bus, a data collision occurs when all slaves try to transmit at the same time (open drain produces a wired-AND result). The resultant family code and 48-bit serial number result in a mismatch of the CRC. Match ROM [55h] The Match ROM command, followed by a 64-bit ROM sequence, allows the bus master to address a specific DS1972 on a multidrop bus. Only the DS1972 that exactly matches the 64-bit ROM sequence responds to the subsequent memory function command. All other slaves wait for a reset pulse. This command can be used with a single device or multiple devices on the bus. Search ROM [F0h] When a system is initially brought up, the bus master might not know the number of devices on the 1-Wire bus or their registration numbers. By taking advantage of the wired-AND property of the bus, the master can use a process of elimination to identify the registration numbers of all slave devices. For each bit of the registration number, starting with the least significant bit, the bus master issues a triplet of time slots. On the first slot, each slave device participating in the search outputs the true value of its registration number bit. On the second slot, each slave device participating in the search outputs the complemented value of its registration number bit. On the third slot, the master writes the true value of the bit to be selected. All slave devices that do not match the bit written by the master stop participating in the search. If both of the read bits are zero, the master knows that slave devices exist with both states of the bit. By choosing which state to write, the bus master branches in the ROM code tree. After one complete pass, the bus master knows the registration number of a single device. Additional passes identify the registration numbers of the remaining devices. Refer to Application Note 187: 1-Wire Search Algorithm for a detailed discussion, including an example. Skip ROM [CCh] This command can save time in a single-drop bus system by allowing the bus master to access the memory functions without providing the 64-bit ROM code. If more than one slave is present on the bus and, for example, a read command is issued following the Skip ROM command, data collision occurs on the bus as multiple slaves transmit simultaneously (open-drain pulldowns produce a wired-AND result). ______________________________________________________________________________________ 13 DS1972 1024-Bit EEPROM iButton BUS MASTER Tx RESET PULSE FROM FIGURE 9b FROM MEMORY FUNCTIONS FLOWCHART (FIGURE 7) OD RESET PULSE? N OD = 0 Y BUS MASTER Tx ROM FUNCTION COMMAND 33h READ ROM COMMAND? DS1972 Tx PRESENCE PULSE N 55h MATCH ROM COMMAND? F0h SEARCH ROM COMMAND? N N CCh SKIP ROM COMMAND? Y Y Y Y RC = 0 RC = 0 RC = 0 RC = 0 DS1972 Tx FAMILY CODE (1 BYTE) MASTER Tx BIT 0 TO FIGURE 9b DS1972 Tx BIT 0 DS1972 Tx BIT 0 MASTER Tx BIT 0 BIT 0 MATCH? N N BIT 0 MATCH? Y Y DS1972 Tx SERIAL NUMBER (6 BYTES) N DS1972 Tx BIT 1 MASTER Tx BIT 1 DS1972 Tx BIT 1 MASTER Tx BIT 1 BIT 1 MATCH? N N BIT 1 MATCH? Y Y DS1972 Tx BIT 63 DS1972 Tx CRC BYTE MASTER Tx BIT 63 DS1972 Tx BIT 63 MASTER Tx BIT 63 BIT 63 MATCH? N N BIT 63 MATCH? Y Y RC = 1 RC = 1 TO FIGURE 9b FROM FIGURE 9b TO MEMORY FUNCTIONS FLOWCHART (FIGURE 7) Figure 9a. ROM Functions Flowchart 14 ______________________________________________________________________________________ 1024-Bit EEPROM iButton DS1972 TO FIGURE 9a FROM FIGURE 9a A5h RESUME COMMAND? 3Ch OVERDRIVESKIP ROM? N Y N Y N Y RC = 0; OD = 1 RC = 1? 69h OVERDRIVEMATCH ROM? RC = 0; OD = 1 N Y MASTER Tx BIT 0 (SEE NOTE) MASTER Tx RESET? N Y BIT 0 MATCH? N OD = 0 Y MASTER Tx BIT 1 MASTER Tx RESET? N Y (SEE NOTE) BIT 1 MATCH? N OD = 0 Y MASTER Tx BIT 63 (SEE NOTE) BIT 63 MATCH? N OD = 0 Y FROM FIGURE 9a RC = 1 TO FIGURE 9a NOTE: THE OD FLAG REMAINS AT 1 IF THE DEVICE WAS ALREADY AT OVERDRIVE SPEED BEFORE THE OVERDRIVE-MATCH ROM COMMAND WAS ISSUED. Figure 9b. ROM Functions Flowchart (continued) ______________________________________________________________________________________ 15 DS1972 1024-Bit EEPROM iButton Resume [A5h] To maximize the data throughput in a multidrop environment, the Resume command is available. This command checks the status of the RC bit and, if it is set, directly transfers control to the memory function commands, similar to a Skip ROM command. The only way to set the RC bit is through successfully executing the Match ROM, Search ROM, or Overdrive-Match ROM command. Once the RC bit is set, the device can repeatedly be accessed through the Resume command. Accessing another device on the bus clears the RC bit, preventing two or more devices from simultaneously responding to the Resume command. Overdrive-Skip ROM [3Ch] On a single-drop bus this command can save time by allowing the bus master to access the memory functions without providing the 64-bit ROM code. Unlike the normal Skip ROM command, the Overdrive-Skip ROM command sets the DS1972 into the overdrive mode (OD = 1). All communication following this command must occur at overdrive speed until a reset pulse of minimum 480µs duration resets all devices on the bus to standard speed (OD = 0). When issued on a multidrop bus, this command sets all overdrive-supporting devices into overdrive mode. To subsequently address a specific overdrive-supporting device, a reset pulse at overdrive speed must be issued followed by a Match ROM or Search ROM command sequence. This speeds up the time for the search process. If more than one slave supporting overdrive is present on the bus and the Overdrive-Skip ROM command is followed by a read command, data collision occurs on the bus as multiple slaves transmit simultaneously (open-drain pulldowns produce a wiredAND result). Overdrive-Match ROM [69h] The Overdrive-Match ROM command followed by a 64bit ROM sequence transmitted at overdrive speed allows the bus master to address a specific DS1972 on a multidrop bus and to simultaneously set it in overdrive mode. Only the DS1972 that exactly matches the 64-bit ROM sequence responds to the subsequent memory function command. Slaves already in overdrive mode from a previous Overdrive-Skip ROM or successful Overdrive-Match ROM command remain in overdrive mode. All overdrive-capable slaves return to standard speed at the next reset pulse of minimum 480µs duration. The Overdrive-Match ROM command can be used with a single device or multiple devices on the bus. 16 1-Wire Signaling The DS1972 requires strict protocols to ensure data integrity. The protocol consists of four types of signaling on one line: reset sequence with reset pulse and presence pulse, write-zero, write-one, and read-data. Except for the presence pulse, the bus master initiates all falling edges. The DS1972 can communicate at two different speeds: standard speed and overdrive speed. If not explicitly set into the overdrive mode, the DS1972 communicates at standard speed. While in overdrive mode, the fast timing applies to all waveforms. To get from idle to active, the voltage on the 1-Wire line needs to fall from VPUP below the threshold VTL. To get from active to idle, the voltage needs to rise from VILMAX past the threshold VTH. The time it takes for the voltage to make this rise is seen in Figure 10 as ε, and its duration depends on the pullup resistor (RPUP) used and the capacitance of the 1-Wire network attached. The voltage VILMAX is relevant for the DS1972 when determining a logical level, not triggering any events. Figure 10 shows the initialization sequence required to begin any communication with the DS1972. A reset pulse followed by a presence pulse indicates that the DS1972 is ready to receive data, given the correct ROM and memory function command. If the bus master uses slew-rate control on the falling edge, it must pull down the line for t RSTL + t F to compensate for the edge. A tRSTL duration of 480µs or longer exits the overdrive mode, returning the device to standard speed. If the DS1972 is in overdrive mode and tRSTL is no longer than 80µs, the device remains in overdrive mode. If the device is in overdrive mode and tRSTL is between 80µs and 480µs, the device resets, but the communication speed is undetermined. After the bus master has released the line it goes into receive mode. Now the 1-Wire bus is pulled to VPUP through the pullup resistor or, in the case of a DS2482x00 or DS2480B driver, through the active circuitry. When the threshold VTH is crossed, the DS1972 waits for tPDH and then transmits a presence pulse by pulling the line low for tPDL. To detect a presence pulse, the master must test the logical state of the 1-Wire line at tMSP. The t RSTH window must be at least the sum of t PDHMAX , t PDLMAX , and t RECMIN . Immediately after tRSTH is expired, the DS1972 is ready for data communication. In a mixed population network, tRSTH should be extended to minimum 480µs at standard speed and 48µs at overdrive speed to accommodate other 1-Wire devices. ______________________________________________________________________________________ 1024-Bit EEPROM iButton DS1972 MASTER Tx "RESET PULSE" MASTER Rx "PRESENCE PULSE" ε tMSP VPUP VIHMASTER VTH VTL VILMAX 0V tRSTL tPDH tF tPDL tREC tRSTH RESISTOR MASTER DS1972 Figure 10. Initialization Procedure: Reset and Presence Pulse Read/Write Time Slots Data communication with the DS1972 takes place in time slots that carry a single bit each. Write time slots transport data from bus master to slave. Read time slots transfer data from slave to master. Figure 11 illustrates the definitions of the write and read time slots. All communication begins with the master pulling the data line low. As the voltage on the 1-Wire line falls below the threshold VTL, the DS1972 starts its internal timing generator that determines when the data line is sampled during a write time slot and how long data is valid during a read time slot. Master-to-Slave For a write-one time slot, the voltage on the data line must have crossed the VTH threshold before the writeone low time tW1LMAX is expired. For a write-zero time slot, the voltage on the data line must stay below the VTH threshold until the write-zero low time tW0LMIN is expired. For the most reliable communication, the voltage on the data line should not exceed VILMAX during the entire tW0L or tW1L window. After the VTH threshold has been crossed, the DS1972 needs a recovery time tREC before it is ready for the next time slot. Slave-to-Master A read-data time slot begins like a write-one time slot. The voltage on the data line must remain below VTL until the read low time tRL is expired. During the tRL window, when responding with a 0, the DS1972 starts pulling the data line low; its internal timing generator determines when this pulldown ends and the voltage starts rising again. When responding with a 1, the DS1972 does not hold the data line low at all, and the voltage starts rising as soon as tRL is over. The sum of tRL + δ (rise time) on one side and the internal timing generator of the DS1972 on the other side define the master sampling window (t MSRMIN to tMSRMAX), in which the master must perform a read from the data line. For the most reliable communication, tRL should be as short as permissible, and the master should read close to but no later than tMSRMAX. After reading from the data line, the master must wait until tSLOT is expired. This guarantees sufficient recovery time tREC for the DS1972 to get ready for the next time slot. Note that tREC specified herein applies only to a single DS1972 attached to a 1-Wire line. For multidevice configurations, tREC must be extended to accommodate the additional 1-Wire device input capacitance. Alternatively, an interface that performs active pullup during the 1-Wire recovery time such as the DS2482x00 or DS2480B 1-Wire line drivers can be used. ______________________________________________________________________________________ 17 DS1972 1024-Bit EEPROM iButton WRITE-ONE TIME SLOT tW1L VPUP VIHMASTER VTH VTL VILMAX 0V ε tF tSLOT RESISTOR MASTER WRITE-ZERO TIME SLOT tW0L VPUP VIHMASTER VTH VTL VILMAX 0V ε tF tREC tSLOT RESISTOR MASTER READ-DATA TIME SLOT tMSR tRL VPUP VIHMASTER VTH MASTER SAMPLING WINDOW VTL VILMAX 0V δ tF tREC tSLOT RESISTOR MASTER DS1972 Figure 11. Read/Write Timing Diagrams 18 ______________________________________________________________________________________ 1024-Bit EEPROM iButton In a 1-Wire environment, line termination is possible only during transients controlled by the bus master (1-Wire driver). 1-Wire networks, therefore, are susceptible to noise of various origins. Depending on the physical size and topology of the network, reflections from end points and branch points can add up or cancel each other to some extent. Such reflections are visible as glitches or ringing on the 1-Wire communication line. Noise coupled onto the 1-Wire line from external sources can also result in signal glitching. A glitch during the rising edge of a time slot can cause a slave device to lose synchronization with the master and, consequently, result in a Search ROM command coming to a dead end or cause a device-specific function command to abort. For better performance in network applications, the DS1972 uses a new 1-Wire front-end, which makes it less sensitive to noise. The DS1972’s 1-Wire front-end differs from traditional slave devices in three characteristics. 1) There is additional lowpass filtering in the circuit that detects the falling edge at the beginning of a time slot. This reduces the sensitivity to high-frequency noise. This additional filtering does not apply at overdrive speed. 2) There is a hysteresis at the low-to-high switching threshold VTH. If a negative glitch crosses VTH but does not go below VTH - VHY, it is not recognized (Figure 12, Case A). The hysteresis is effective at any 1-Wire speed. 3) There is a time window specified by the rising edge hold-off time tREH during which glitches are ignored, even if they extend below the VTH - VHY threshold tREH (Figure 12, Case B, tGL < tREH). Deep voltage drops or glitches that appear late after crossing the VTH threshold and extend beyond the tREH window cannot be filtered out and are taken as the beginning of a new time slot (Figure 12, Case C, tGL ≥ tREH). Devices that have the parameters VHY and tREH specified in their electrical characteristics use the improved 1-Wire front-end. CRC Generation The DS1972 uses two different types of CRCs. One CRC is an 8-bit type and is stored in the most significant byte of the 64-bit ROM. The bus master can compute a CRC value from the first 56 bits of the 64-bit ROM and compare it to the value stored within the DS1972 to determine if the ROM data has been received error-free. The equivalent polynomial function of this CRC is X 8 + X 5 + X 4 + 1. This 8-bit CRC is received in the true (noninverted) form. It is computed at the factory and lasered into the ROM. The other CRC is a 16-bit type, generated according to the standardized CRC-16 polynomial function X16 + X15 + X2 + 1. This CRC is used for fast verification of a data transfer when writing to or reading from the scratchpad. In contrast to the 8-bit CRC, the 16-bit CRC is always communicated in the inverted form. A CRC generator inside the DS1972 iButton (Figure 13) calculates a new 16-bit CRC, as shown in the command flowchart (Figure 7). The bus master compares the CRC value read from the device to the one it calculates from the data and decides whether to continue with an operation or to reread the portion of the data with the CRC error. With the Write Scratchpad command, the CRC is generated by first clearing the CRC generator and then shifting in the command code, the target addresses TA1 and TA2, and all the data bytes as they were sent tREH VPUP VTH VHY CASE A CASE B CASE C 0V tGL tGL Figure 12. Noise Suppression Scheme ______________________________________________________________________________________ 19 DS1972 Improved Network Behavior (Switchpoint Hysteresis) DS1972 1024-Bit EEPROM iButton POLYNOMIAL = X16 + X15 + X2 + 1 1ST STAGE 3RD STAGE 2ND STAGE X0 X2 X1 9TH STAGE X8 4TH STAGE 10TH STAGE X9 11TH STAGE X10 X3 12TH STAGE X11 5TH STAGE 6TH STAGE X4 13TH STAGE X12 X5 14TH STAGE X13 7TH STAGE X6 8TH STAGE X7 15TH STAGE X14 16TH STAGE X15 X16 CRC OUTPUT INPUT DATA Figure 13. CRC-16 Hardware Description and Polynomial by the bus master. The DS1972 transmits this CRC only if E[2:0] = 111b. With the Read Scratchpad command, the CRC is generated by first clearing the CRC generator and then shifting in the command code, the target addresses TA1 and TA2, the E/S byte, and the scratchpad data as they were sent by the DS1972. The DS1972 transmits this CRC only if the reading continues through the end of the scratchpad. For more information on generating CRC values, refer to Application Note 27. Command-Specific 1-Wire Communication Protocol—Legend SYMBOL RST PD Select 1-Wire presence pulse generated by slave. Command and data to satisfy the ROM function protocol. WS Command “Write Scratchpad.” RS Command “Read Scratchpad.” CPS Command “Copy Scratchpad.” RM Command “Read Memory.” TA Target address TA1, TA2. TA-E/S <8–T[2:0] bytes> <Data to EOM> Target address TA1, TA2 with E/S byte. Transfer of as many bytes as needed to reach the end of the scratchpad for a given target address. Transfer of as many data bytes as are needed to reach the end of the memory. CRC-16 Transfer of an inverted CRC-16. FF Loop Indefinite loop where the master reads FF bytes. AA Loop Indefinite loop where the master reads AA bytes. Programming 20 DESCRIPTION 1-Wire reset pulse generated by master. Data transfer to EEPROM; no activity on the 1-Wire bus permitted during this time. ______________________________________________________________________________________ 1024-Bit EEPROM iButton Master to Slave Slave to Master Programming 1-Wire Communication Examples Write Scratchpad (Cannot Fail) RST PD Select WS TA <8–T[2:0] bytes> CRC-16 FF Loop Read Scratchpad (Cannot Fail) RST PD Select RS TA-E/S <8–T[2:0] bytes> CRC-16 FF Loop Copy Scratchpad (Success) RST PD Select CPS TA-E/S Programming AA Loop Copy Scratchpad (Invalid Address or PF = 1 or Copy Protected) RST PD Select CPS TA-E/S FF Loop Read Memory (Success) RST PD Select RM TA <Data to EOM> FF Loop Read Memory (Invalid Address) RST PD Select RM TA FF Loop ______________________________________________________________________________________ 21 DS1972 Command-Specific 1-Wire Communication Protocol—Color Codes DS1972 1024-Bit EEPROM iButton Memory Function Example Write to the first 8 bytes of memory page 1. Read the entire memory. MASTER MODE Tx Rx Tx Tx Tx Tx Tx Rx Tx Rx Tx Tx Rx Rx Rx Rx Rx Tx Rx Tx Tx Tx Tx Tx — Rx Tx Rx Tx Tx Tx Tx Rx Tx Rx With only a single DS1972 connected to the bus master, the communication looks like this: DATA (LSB FIRST) (Reset) (Presence) CCh 0Fh 20h 00h <8 Data Bytes> <2 Bytes CRC-16> (Reset) (Presence) CCh AAh 20h 00h 07h <8 Data Bytes> <2 Bytes CRC-16> (Reset) (Presence) CCh 55h 20h 00h 07h <1-Wire Idle High> AAh (Reset) (Presence) CCh F0h 00h 00h <144 Data Bytes> (Reset) (Presence) COMMENTS Reset pulse Presence pulse Issue “Skip ROM” command Issue “Write Scratchpad” command TA1, beginning offset = 20h TA2, address = 0020h Write 8 bytes of data to scratchpad Read CRC to check for data integrity Reset pulse Presence pulse Issue “Skip ROM” command Issue “Read Scratchpad” command Read TA1, beginning offset = 20h Read TA2, address = 0020h Read E/S, ending offset = 111b, AA, PF = 0 Read scratchpad data and verify Read CRC to check for data integrity Reset pulse Presence pulse Issue “Skip ROM” command Issue “Copy Scratchpad” command TA1 (AUTHORIZATION CODE) TA2 E/S Wait t PROGMAX for the copy function to complete Read copy status, AAh = success Reset pulse Presence pulse Issue “Skip ROM” command Issue “Read Memory” command TA1, beginning offset = 00h TA2, address = 0000h Read the entire memory Reset pulse Presence pulse Package Information For the latest package outline information and land patterns, go to www.maxim-ic.com/packages. Note that a “+”, “#”, or “-” in the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the package regardless of RoHS status. 22 PACKAGE TYPE PACKAGE CODE DOCUMENT NO. F3 iButton IB+3NT 21-0252 F5 iButton IB+5NT 21-0266 ______________________________________________________________________________________ 1024-Bit EEPROM iButton REVISION NUMBER REVISION DATE 0 4/06 Initial release 1 8/06 UL#913 bullet changed from “Meets UL#93 (4th Edit.). . .(Application Pending)” to “Designed to meet UL#93 (4th Edit.). . .” 2 8/09 3 4 4/10 1/12 DESCRIPTION PAGES CHANGED — 1, 2 Deleted UL#913 bullet from the Common iButton Features section. 1 Changed the RoHS packages to lead(Pb)-free packages in the Ordering Information table. 1 Changed VTLMIN from 0.46V to 0.5V in the Electrical Characteristics table. 2 In the Absolute Maximum Ratings, changed storage temp to -55°C to +125°C; in the Electrical Characteristics table, changed VTH, VTL based on VPUP and data retention to 40 years min at 85°C; added note to retention spec: “EEPROM writes can become nonfunctional after the data-retention time is exceeded. Long-term storage at elevated temperatures is not recommended; the device can lose its write capability after 10 years at +125°C or 40 years at +85°C.” 2, 3 In the Electrical Characteristics table, changed the VILMAX spec from 0.3V to 0.5V; removed from the tW1LMAX spec; added Note 17 to tW0L spec; updated EC table Notes 17 and 18; corrected Note 20. 2, 3 Added to Figure 11 Write-Zero Time Slot. 18 Added Package Information table. 22 Created newer template-style data sheet. All Updated Note 1 in the Electrical Characteristics section; specified the data memory default status and added a note that the memory must be programmed to FFh for the EPROM mode to function to the Memory Access section. 3, 7, 8 Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time. Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________ 23 © 2012 Maxim Integrated Products Maxim is a registered trademark of Maxim Integrated Products, Inc. DS1972 Revision History