DS2740 High-Precision Coulomb Counter www.maxim-ic.com FEATURES § § § § § § 15-Bit Bidirectional Current Measurement (DS2740) § 1.56mV LSB and ±51.2mV Dynamic Range § 78mA LSB and ±2.56A Dynamic Range with External 20mW Sense Resistor (RSNS) § 156mA LSB and ±5.12A Dynamic Range with External 10mW Sense Resistor (RSNS) 13-Bit Bidirectional Current Measurement (DS2740B) § 6.25mV LSB and ±51.2mV Dynamic Range § 312mA LSB and ±2.56A Dynamic Range with External 20mW Sense Resistor (RSNS) § 625mA LSB and ±5.12A Dynamic Range with External 10mW Sense Resistor (RSNS) Analog Input Filter (IS1, IS2) Extends Dynamic Range for Pulse-Load Applications Current Accumulation Register Resolution § 6.25mVhr (Both DS2740 and DS2740B) § 0.3125mAhr with External 20mW RSNS § 0.6250mAhr with External 10mW RSNS Dallas 1-Wire® Interface § Unique 64-Bit Device Address § Standard and Overdrive Timings (OVD) Low Power Consumption: § Active Current: 65mA max § Sleep Current: 1mA max PIN CONFIGURATION OVD PIO 1 8 VDD 2 7 DQ SNS IS2 3 6 VSS 4 5 IS1 mMAX (DS2740U, DS2740BU) See Table 1 for Ordering Information. See Table 2 for Detailed Pin Descriptions. PIN DESCRIPTION OVD- 1-Wire Bus Speed Select PIO - Programmable I/O Pin SNS - Sense Resistor Input IS2 - Current-Sense Input IS1 - Current-Sense Input VSS - Device Ground, Current-Sense Resistor Return DQ - Data Input/Output VDD - Power-Supply Input (2.7V to 5.5V) 1-Wire is a registered trademark of Dallas Semiconductor. 1 of 15 033103 DS2740 Table 1. ORDERING INFORMATION PART DS2740U DS2740U/T&R DS2740BU DS2740BU/T&R MARKING DS2740 DS2740 DS2740B DS2740B PIN-PACKAGE 15-Bit Current Resolution, mMAX 15-Bit Current Resolution, mMAX, Tape-and-Reel 13-Bit Current Resolution, mMAX 13-Bit Current Resolution, mMAX, Tape-and-Reel DESCRIPTION The DS2740 provides high-precision current-flow measurement data to support battery-capacity monitoring in cost-sensitive applications. Current is measured bidirectionally over a dynamic range of 15 bits (DS2740U) or 13 bits (DS2740UB), with the net flow accumulated in a separate 16-bit register. Through its 1-Wire interface, the DS2740 allows the host system read/write access to status and current measurement registers. Each device has a unique factory-programmed 64-bit net address that allows it to be individually addressed by the host system, supporting multibattery slot operation. The interface can be operated with standard or overdrive timing. Although the DS2740 is primarily intended for location on the host system, it is also suited for mounting in the battery pack. The DS2740 and FuelPack™ algorithms, along with host measurements of temperature and voltage, form a complete and accurate solution for estimating remaining capacity. Figure 1. BLOCK DIAGRAM VDD DQ PIO STATUS/CONTROL 1-WIRE INTERFACE AND ADDRESS ACCUMULATED CURRENT TIMEBASE CURRENT 15-Bit + Sign ADC RIS 10 kW RIS 10 kW SNS IS2 IS1 FuelPack is a trademark of Dallas Semiconductor. 2 of 15 CHIP GROUND VSS DS2740 Table 2. DETAILED PIN DESCRIPTION PIN SYMBOL DESCRIPTION OVD 1 1-Wire Bus Speed Control. Input logic level selects the speed of the 1Wire bus. Logic 1 selects overdrive (OVD) and Logic 0 selects standard timing (STD). On a multidrop bus, all devices must operate at same speed. PIO 2 Programmable I/O Pin. Programmed as input or output through internal registers. Open-drain output sufficient for LED or vibrator activation. SNS 3 IS2 4 IS1 5 VSS 6 Device Ground, Current-Sense Resistor Return. Connect directly to the negative terminal of the battery cell. DQ 7 Data I/O Pin. Operates bidirectionally with open-drain output driver. Internal 1µA pulldown aids in sensing pack removal and sleep-mode activation. VDD 8 Power-Supply Input. Connects to system voltage supply or positive terminal of battery cell. Current-Sense Resistor Input Current-Sense Input. Connected to SNS through a 10kΩ resistor to allow filtering of the current waveform by an external capacitor. Current-Sense Input. Connected to VSS through a 10kΩ resistor to allow filtering of the current waveform through an external capacitor. Figure 2. APPLICATION EXAMPLE 2.7V to 5.5V System Supply Battery Pack DATA PIO 150 VDD 150 DQ 104 DS2740 150 * * PIO OVD SNS VSS IS2 IS1 System GND 104 Negative Battery Pack Return RSNS * 5.6V zener recommended for ESD protection when DATA or PIO contacts exposed, such as a removable battery pack application 3 of 15 DS2740 POWER MODES The DS2740 has two power modes: active and sleep. While in active mode, the DS2740 operates as a high-precision coulomb counter with current and accumulated current measurement blocks operating continuously and the resulting values updated in the measurement registers. Read and write access is allowed to all registers. PIO pin is active. In sleep mode, the DS2740 operates in a low-power mode with no current measurement activity. Serial access to current, accumulated current, and status/control registers is allowed if VDD > 2V. The DS2740 operating mode transitions from SLEEP to ACTIVE when: 1) DQ > VIH, and VDD > UV threshold, or 2) VDD rises from below UV threshold to above UV threshold. The DS2740 operating mode transitions from ACTIVE to SLEEP when: 1) VDD falls to UV threshold, or 2) SMOD = 1 and DQ < VIL for 2s. CURRENT MEASUREMENT In the active mode of operation, the DS2740 continually measures the current flow into and out of the battery by measuring the voltage drop across a low-value current-sense resistor, RSNS. To extend the input range for pulse-type load currents, the voltage signal can be filtered by adding a capacitor between the IS1 and IS2 pins. The external capacitor and two internal resistors form a lowpass filter at the input of the ADC. The voltage-sense range at IS1 and IS2 is ±51.2mV. The input converts peak signal amplitudes up to 75mV as long as the continuous or average signal level (post filter) does not exceed ±51.2mV over the conversion cycle period. The ADC samples the input differentially at IS1 and IS2 with an 18.6kHz sample clock and updates the current register at the completion of each conversion cycle. Conversion times for each resolution option are listed in the tables below. Two resolution options are available. Figure 3 describes the current measurement register format and resolution for each option. “S” indicates the sign bit(s). Figure 3. CURRENT REGISTER FORMATS DS2740: 15-bit + sign resolution, 3.5s conversion period. MSB—Address 0E S 214 213 212 211 210 LSB—Address 0F 29 MSb 28 27 LSb MSb 26 25 24 23 22 21 20 LSb Units: 1.5625mV/Rsns DS2740B: 13-bit + sign resolution, 0.875s conversion period. MSB—Address 0E S MSb S S 212 211 210 LSB—Address 0F 29 28 27 LSb MSb 4 of 15 26 25 24 23 22 21 20 LSb Units: 6.250mV/Rsns DS2740 PART CONVERSION TIME DS2740 DS2740B 3.515s 0.878s CURRENT RESOLUTION (1 LSB) RSNS VIS1 - VIS2 20mW 15mW 10mW 5mW 1.5625mV 78.13mA 104.2mA 156.3mA 312.5mA 1.250mA 6.250mV 312.5mA 416.7mA 625mA Every 1024th conversion, the ADC measures its input offset to facilitate offset correction. Offset correction occurs approximately once per hour in the DS2740 and four times per hour in the DS2740B. The resulting correction factor is applied to the subsequent 1023 measurements. During the offset correction conversion, the ADC does not measure the IS1 to IS2 signal. A maximum error of 1/1024 in the accumulated current register (ACR) is possible, however, to reduce the error, the current measurement just prior to the offset conversion is displayed in the current register and is substituted for the dropped current measurement in the current accumulation process. The typical error due to offset correction is much less than 1/1024. CURRENT ACCUMULATOR Current measurements are internally summed, or accumulated, at the completion of each conversion period with the results displayed in the ACR. The accuracy of the ACR is dependent on both the current measurement and the conversion timebase. The ACR has a range of ±204.8mVh with an LSb of 6.25µVh. Additional registers hold fractional results of each accumulation, however, these bits are not user accessible. Read and write access is allowed to the ACR. Whenever the ACR is written, fractional accumulation results are cleared. Also, a write forces the ADC to measure its offset and update the offset correction factor. The current measurement and accumulation begin with the second conversion following a write to the ACR. Figure 4 describes the ACR address, format, and resolution. Figure 4. CURRENT ACCUMULATOR FORMAT MSB—Address 10 S 214 213 212 211 210 MSb PART DS2740 DS2740B UPDATE INTERVAL 3.515s 0.878s VIS1- VIS2 6.25mVh LSB—Address 11 29 28 27 LSb MSb 20mW 312.5mAh 5 of 15 26 25 24 22 21 20 LSb Units: 6.25mVh/Rsns ACR LSB RSNS 15mW 10mW 416.7mAh 23 625mAh 5mW 1.250mAh DS2740 PART DS2740 DS2740B VIS1- VIS2 ±204.8mVh ACR RANGE RSNS 20mW 15mW 10mW ±10.24Ah ±13.65Ah ±20.48Ah 5mW ±40.96Ah MEMORY The DS2740 has memory space with registers for instrumentation, status, and control. When the MSB of a two-byte register is read, both the MSB and LSB are latched and held for the duration of the read data command to prevent updates during the read and ensure synchronization between the two register bytes. For consistent results, always read the MSB and the LSB of a two-byte register during the same read data command sequence. Table 3. MEMORY MAP ADDRESS (HEX) 00 01 02 to 07 08 09 to 0D 0E 0F 10 11 12 to FF DESCRIPTION Reserved Status Register Reserved Special Feature Register Reserved Current Register MSB Current Register LSB Accumulated Current Register MSB Accumulated Current Register LSB Reserved READ/WRITE — R — R/W — R R R/W R/W — STATUS REGISTER The format of the status register is shown in Figure 5. The function of each bit is described in detail in the following paragraphs. Figure 5. STATUS REGISTER FORMAT ADDRESS 01 BIT 7 X BIT 6 SMOD BIT 5 X BIT 4 RNAOP BIT 3 X BIT 2 X BIT 1 X BIT 0 X SMOD—SLEEP Mode Enable. A value of 1 allows the DS2740 to enter sleep mode when DQ is low for 2s. A value of 0 disables DQ related transitions to sleep mode. The power-up default of SMOD = 0. RNAOP—Read Net Address Opcode. A value of 0 in this bit sets the opcode for the read net address command to 33h, while a 1 sets the opcode to 39h. The power-up default of RNAOP = 0. X—Reserved bits. 6 of 15 DS2740 SPECIAL FEATURE REGISTER The format of the special feature register is shown in Figure 6. The function of each bit is described in detail in the following paragraphs. Figure 6. SPECIAL FEATURE REGISTER FORMAT ADDRESS 08 BIT 7 BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 BIT 0 X PIO X X X X X X PIO—PIO Pin Sense and Control. This bit is read and write enabled. Writing a 0 to the PIO bit enables the PIO open-drain output driver, forcing the PIO pin low. Writing a 1 to the PIO bit disables the output driver, allowing the PIO pin to be pulled high or used as an input. Reading the PIO bit returns the logic level forced on the PIO pin. Note that if PIO is left floating, the weak pulldown brings the pin low. X—Reserved Bits. 1-WIRE BUS SYSTEM The 1-Wire bus is a system that has a single bus master and one or more slaves. A multidrop bus is a 1-Wire bus with multiple slaves. A single-drop bus has only one slave device. In all instances, the DS2740 is a slave device. The bus master is typically a microprocessor in the host system. The discussion of this bus system consists of four topics: 64-bit net address, hardware configuration, transaction sequence, and 1-Wire signaling. 64-BIT NET ADDRESS Each DS2740 has a unique, factory-programmed 1-Wire net address that is 64 bits in length. The first eight bits are the 1-Wire family code (36h for DS2740). The next 48 bits are a unique serial number. The last eight bits are a cyclic redundancy check (CRC) of the first 56 bits (see Figure 7). The 64-bit net address and the 1-Wire I/O circuitry built into the device enable the DS2740 to communicate through the 1-Wire protocol detailed in the 1-Wire Bus System section of this data sheet. Figure 7. 1-WIRE NET ADDRESS FORMAT 8-BIT CRC 48-BIT SERIAL NUMBER MSb 8-BIT FAMILY CODE (36h) LSb CRC GENERATION The DS2740 has an 8-bit CRC stored in the most significant byte of its 1-Wire net address. To ensure error-free transmission of the address, the host system can compute a CRC value from the first 56 bits of the address and compare it to the CRC from the DS2740. The host system is responsible for verifying the CRC value and taking action as a result. The DS2740 does not compare CRC values and does not prevent a command sequence from proceeding as a result of a CRC mismatch. Proper use of the CRC can result in a communication channel with a very high level of integrity. The CRC can be generated by the host using a circuit consisting of a shift register and XOR gates as shown in Figure 8, or it can be generated in software. Additional information about the Dallas 1-Wire 7 of 15 DS2740 CRC is available in Application Note 27, Understanding and Using Cyclic Redundancy Checks with Dallas Semiconductor Touch Memory Products. (This application note can be found on the Maxim/Dallas Semiconductor website at www.maxim-ic.com.) In the circuit in Figure 8, 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, then the serial number is entered. After the 48th bit of the serial number has been entered, the shift register contains the CRC value. Figure 8. 1-WIRE CRC GENERATION BLOCK DIAGRAM INPUT MSb XOR XOR LSb XOR HARDWARE CONFIGURATION Because the 1-Wire bus has only a single line, 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 connect to the bus with open-drain or tri-state output drivers. The DS2740 uses an open-drain output driver as part of the bidirectional interface circuitry shown in Figure 9. If a bidirectional pin is not available on the bus master, separate output and input pins can be connected together. The 1-Wire bus must have a pullup resistor at the bus-master end of the bus. For short line lengths, the value of this resistor should be approximately 5kW. The idle state for the 1-Wire bus is high. If, for any reason, a bus transaction must be suspended, the bus must be left in the idle state to properly resume the transaction later. If the bus is left low for more than 120ms (16ms for overdrive speed), slave devices on the bus begin to interpret the low period as a reset pulse, effectively terminating the transaction. The DS2740 can operate in two communication speed modes, standard and overdrive. The speed mode is determined by the input logic level of the OVD pin with a logic 0 selecting standard speed and a logic 1 selecting overdrive speed. The OVD pin must be at a stable logic level of 0 or 1 before initializing a transaction with a reset pulse. All 1-Wire devices on a multinode bus must operate at the same communication speed for proper operation. 1-Wire timing for both standard and overdrive speeds are listed in the Electrical Characteristics: 1-Wire Interface tables. 8 of 15 DS2740 Figure 9. 1-WIRE BUS INTERFACE CIRCUITRY BUS MASTER Vpullup (2.0V to 5.5V) DS2740 1-WIRE PORT 4.7kW Rx Rx 1mA (typ) Tx Rx = RECEIVE Tx = TRANSMIT Tx 100W MOSFET TRANSACTION SEQUENCE The protocol for accessing the DS2740 through the 1-Wire port is as follows: § § § § Initialization Net Address Command Function Command Transaction/Data The sections that follow describe each of these steps in detail. All transactions of the 1-Wire bus begin with an initialization sequence consisting of a reset pulse transmitted by the bus master followed by a presence pulse simultaneously transmitted by the DS2740 and any other slaves on the bus. The presence pulse tells the bus master that one or more devices are on the bus and ready to operate. For more details, see the 1-Wire Signaling section. NET ADDRESS COMMANDS Once the bus master has detected the presence of one or more slaves, it can issue one of the net address commands described in the following paragraphs. The name of each ROM command is followed by the 8-bit opcode for that command in square brackets. Figure 10 presents a transaction flowchart of the net address commands. Read Net Address [33h or 39h]. This command allows the bus master to read the DS2740’s 1-Wire net address. This command can only be used if there is a single slave on the bus. If more than one slave is present, a data collision occurs when all slaves try to transmit at the same time (open drain produces a wired-AND result). The RNAOP bit in the status register selects the opcode for this command, with RNAOP = 0 indicating 33h, and RNAOP = 1 indicating 39h. Match Net Address [55h]. This command allows the bus master to specifically address one DS2740 on the 1-Wire bus. Only the addressed DS2740 responds to any subsequent function command. All other slave devices ignore the function command and wait for a reset pulse. This command can be used with one or more slave devices on the bus. 9 of 15 DS2740 Skip Net Address [CCh]. This command saves time when there is only one DS2740 on the bus by allowing the bus master to issue a function command without specifying the address of the slave. If more than one slave device is present on the bus, a subsequent function command can cause a data collision when all slaves transmit data at the same time. Search Net Address [F0h]. This command allows the bus master to use a process of elimination to identify the 1-Wire net addresses of all slave devices on the bus. The search process involves the repetition of a simple three-step routine: read a bit, read the complement of the bit, then write the desired value of that bit. The bus master performs this simple three-step routine on each bit location of the net address. After one complete pass through all 64 bits, the bus master knows the address of one device. The remaining devices can then be identified on additional iterations of the process. See Chapter 5 of the Book of DS19xx iButton® Standards for a comprehensive discussion of a net address search, including an actual example. (This publication can be found on the Maxim/Dallas Semiconductor website at www.maximic.com.) Resume [A5h]. This command increases data throughput in multidrop environments where the DS2740 needs to be accessed several times. Resume is similar to the Skip Net Address command in that the 64bit net address does not have to be transmitted each time the DS2740 is accessed. After successfully executing a Match Net Address command or Search Net Address command, an internal flag is set in the DS2740. When the flag is set, the DS2740 can be repeatedly accessed through the Resume command function. Accessing another device on the bus clears the flag, thus preventing two or more devices from simultaneously responding to the Resume command function. FUNCTION COMMANDS After successfully completing one of the net address commands, the bus master can access the features of the DS2740 with any of the function commands described in the following paragraphs and summarized in Table 4. The name of each function is followed by the 8-bit opcode for that command in square brackets. Read Data [69h, XX]. This command reads data from the DS2740 starting at memory address XX. The LSb of the data in address XX is available to be read immediately after the MSb of the address has been entered. Because the address is automatically incremented after the MSb of each byte is received, the LSb of the data at address XX + 1 is available to be read immediately after the MSb of the data at address XX. If the bus master continues to read beyond address FFh, the DS2740 starts over at address 00h. Addresses labeled “Reserved” in the memory map contain undefined data. The read data command can be terminated by the bus master with a reset pulse at any bit boundary. Write Data [6Ch, XX]. This command writes data to the DS2740 starting at memory address XX. The LSb of the data to be stored at address XX can be written immediately after the MSb of address has been entered. Because the address is automatically incremented after the MSb of each byte is written, the LSb to be stored at address XX + 1 can be written immediately after the MSb to be stored at address XX. If the bus master continues to write beyond address FFh, the DS2740 starts over writing at address 00h. Writes to read-only addresses and reserved addresses are ignored. Incomplete bytes are not written. See the Memory section for more details. iButton is a registered trademark of Dallas Semiconductor. 10 of 15 DS2740 Figure 10. NET ADDRESS COMMAND FLOW CHART MASTER Tx RESET PULSE DS2740 Tx PRESENCE PULSE MASTER Tx NET ADDRESS COMMAND 33h / 39h READ NO 55h MATCH YES NO F0h SEARCH YES YES MASTER Tx BIT 0 DS2740 Tx FAMILY CODE 1 BYTE DS2740 Tx BIT 0 DS2740 Tx BIT 0 NO CCh SKIP YES MASTER Tx FUNCTION COMMAND NO A5h RESUME YES RESUME FLAG SET ? MASTER Tx BIT 0 DS2740 Tx SERIAL NUMBER 6 BYTES YES BIT 0 MATCH ? DS2740 Tx CRC 1 BYTE NO NO YES BIT 0 MATCH ? YES MASTER Tx BIT 1 DS2740 Tx BIT 1 DS2740 Tx BIT 1 MASTER Tx BIT 1 BIT 1 MATCH ? YES MASTER Tx BIT 63 MASTER Tx FUNCTION COMMAND NO NO BIT 1 MATCH ? YES DS2740 Tx BIT 63 DS2740 Tx BIT 63 MASTER Tx BIT 63 SET RESUME FLAG YES BIT 63 MATCH ? NO 11 of 15 NO MASTER Tx FUNCTION COMMAND NO DS2740 Table 4. FUNCTION COMMANDS COMMAND Read Data Write Data DESCRIPTION COMMAND PROTOCOL BUS STATE AFTER COMMAND PROTOCOL BUS DATA 69h, XX Master Rx Up to 256 bytes of data 6Ch, XX Master Tx Up to 256 bytes of data Reads data from memory starting at address XX Writes data to memory starting at address XX 1-WIRE SIGNALING The 1-Wire bus requires strict signaling protocols to ensure data integrity. The four protocols used by the DS2740 are as follows: the initialization sequence (reset pulse followed by presence pulse), write 0, write 1, and read data. All of these types of signaling except the presence pulse are initiated by the bus master. The initialization sequence required to begin any communication with the DS2740 is shown in Figure 11. A presence pulse following a reset pulse indicates that the DS2740 is ready to accept a net address command. The bus master transmits (Tx) a reset pulse for tRSTL. The bus master then releases the line and goes into receive mode (Rx). The 1-Wire bus line is then pulled high by the pullup resistor. After detecting the rising edge on the DQ pin, the DS2740 waits for tPDH and then transmits the presence pulse for tPDL. Figure 11. 1-WIRE INITIALIZATION SEQUENCE tRSTL tRSTH tPDH tPDL PACK+ DQ PACKLINE TYPE LEGEND: BUS MASTER ACTIVE LOW DS2740 ACTIVE LOW BOTH BUS MASTER AND DS2740 ACTIVE LOW RESISTOR PULLUP WRITE-TIME SLOTS A write-time slot is initiated when the bus master pulls the 1-Wire bus from a logic-high (inactive) level to a logic-low level. There are two types of write-time slots: write 1 and write 0. All write-time slots must be tSLOT in duration with a 1ms minimum recovery time, tREC, between cycles. The DS2740 samples the 1-Wire bus line between 15ms and 60ms (between 2ms and 6ms for overdrive speed) after the line falls. If the line is high when sampled, a write 1 occurs. If the line is low when sampled, a write 0 occurs (see Figure 12). For the bus master to generate a write 1 time slot, the bus line must be pulled low and then released, allowing the line to be pulled high within 15ms (2ms for overdrive speed) after the start of the write-time slot. For the host to generate a write 0 time slot, the bus line must be pulled low and held low for the duration of the write-time slot. 12 of 15 DS2740 READ-TIME SLOTS A read-time slot is initiated when the bus master pulls the 1-Wire bus line from a logic-high level to a logic-low level. The bus master must keep the bus line low for at least 1ms and then release it to allow the DS2740 to present valid data. The bus master can then sample the data tRDV from the start of the readtime slot. By the end of the read-time slot, the DS2740 releases the bus line and allows it to be pulled high by the external pullup resistor. All read-time slots must be tSLOT in duration with a 1ms minimum recovery time, tREC, between cycles. See Figure 12 for more information. Figure 12. 1-WIRE WRITE- AND READ-TIME SLOTS WRITE 0 SLOT tSLOT tLOW0 WRITE 1 SLOT tSLOT tLOW1 tREC VPULLUP GND Mode MIN DS2740 Sample Window TYP MAX MIN >1ms DS2740 Sample Window TYP MAX Standard 15ms 15ms 30ms 15ms 15ms 30ms Overdrive 2ms 1ms 3ms 2ms 1ms 3ms READ 0 SLOT tSLOT READ 1 SLOT tSLOT tREC VPULLUP GND Master Sample Window tRDV >1ms Master Sample Window tRDV LINE TYPE LEGEND: Bus master active low DS2740 active low Both bus master and DS2740 active low Resistor pullup 13 of 15 DS2740 ABSOLUTE MAXIMUM RATINGS* Voltage on VDD, DQ, IS1, IS2, PIO, Relative to VSS Voltage on SNS, Relative to VSS Operating Temperature Range Storage Temperature Range Soldering Temperature -0.3V to +6V -0.3V to +6V -40°C to +85°C -55°C to +125°C See IPC/JEDECJ-STD-020A * This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operation sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods of time may affect reliability. RECOMMENDED DC OPERATING CONDITIONS (2.7V £ VDD £ 5.5V; TA = 0°C to +70°C.) PARAMETER Supply Voltage Data Pin SYMBOL CONDITIONS VDD (Note 1) DQ (Note 1) DC ELECTRICAL CHARACTERISTICS (2.7V £ VDD £ 4.2V; TA = 0°C to +70°C.) PARAMETER SYMBOL Active Current IACTIVE Sleep-Mode Current ISLEEP Undervoltage Sleep Threshold VUV Current Resolution ILSB Current Full-Scale Magnitude Current Measurement Offset (Auto Calibrated) Current Gain Error Accumulated Current Resolution Current Sample Clock Frequency Timebase Accuracy Input Logic High: OVD Input Logic High: DQ, PIO Input Logic Low: OVD CONDITIONS MIN 2.7 -0.3 TYP MAX 5.5 +5.5 UNITS V V MIN TYP 50 MAX 65 85 UNITS 0.6 1.0 VDD = 5.5V VDD = 2.0V, DQ = PIO = VSS VDD = 4.2V, DQ = PIO = VSS 2.3 DS2740 DS27640B 2.5 2.7 +1 +5 DS2740B (Note 2) -2 0 +2 qCA fSAMP VDD = 3.5V at +25°C VIH (Note 1) VIH (Note 1) VIL (Note 1) -1 -4 VDD 0.2V +1 LSb % of reading 6.25 mVh 18.6 kHz +1 +4 % V 1.5 V VSS + 0.2 14 of 15 V mV -3 -1 mA mV DS2740 (Note 2) IGERR tERR 1.25 1.56 6.25 51.2 IFS IOERR 0.9 mA V DS2740 Input Logic Low: DQ, PIO Output Logic Low: DQ, PIO DQ, PIO Input Pulldown Current OVD Input Leakage DQ Capacitance DQ Low to Sleep Time VIL (Note 1) 0.6 V VOL IOL = 4mA (Note 1) 0.4 V IPD ILOVD CDQ tSLEEP VDD = 4.2V, VDQ = 0.4V PIO bit = 1 -1 (Note 3) 2.0 mA 0.5 ELECTRICAL CHARACTERISTICS: 1-WIRE INTERFACE—STANDARD SPEED (2.7V £ VDD £ 5.5V; TA = -20°C to +70°C.) PARAMETER Time Slot Recovery Time Write 0 Low Time Write 1 Low Time Read Data Valid Reset Time High Reset Time Low Presence Detect High Presence Detect Low SYMBOL tSLOT tREC tLOW0 tLOW1 tRDV tRSTH tRSTL tPDH tPDL MIN 60 1 60 1 TYP MAX 120 120 15 15 480 480 15 60 960 60 240 ELECTRICAL CHARACTERISTICS: 1-WIRE INTERFACE—OVERDRIVE SPEED (2.7V £ VDD £ 5.5V; TA = -20°C to +70°C.) PARAMETER Time Slot Recovery Time Write 0 Low Time Write 1 Low Time Read Data Valid Reset Time High Reset Time Low Presence Detect High Presence Detect Low Note 1: Note 2: Note 3: SYMBOL tSLOT tREC tLOW0 tLOW1 tRDV tRSTH tRSTL tPDH tPDL MIN 6 1 6 1 48 48 2 8 mA pF s 1 50 2.4 TYP MAX 16 16 2 2 80 6 24 UNITS ms ms ms ms ms ms ms ms ms UNITS ms ms ms ms ms ms ms ms ms All voltages are referenced to VSS. Offset performance requires proper circuit layout design free of surface contaminants. The DS2740 enters the sleep mode 2.0s to 2.4s after DQ goes low. 15 of 15