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 19-5210; Rev 3; 4/10
KIT ATION EVALU BLE AVAILA
Compact, Low-Cost 1S/2S Fuel Gauges
General Description
The MAX17040/MAX17041 are ultra-compact, low-cost, host-side fuel-gauge systems for lithium-ion (Li+) batteries in handheld and portable equipment. The MAX17040 is configured to operate with a single lithium cell and the MAX17041 is configured for a dual-cell 2S pack. The MAX17040/MAX17041 use a sophisticated Li+ battery-modeling scheme, called ModelGaugeTM to track the battery's relative state-of-charge (SOC) continuously over a widely varying charge/discharge profile. Unlike traditional fuel gauges, the ModelGauge algorithm eliminates the need for battery relearn cycles and an external current-sense resistor. Temperature compensation is possible in the application with minimal interaction between a C and the device. A quick-start mode provides a good initial estimate of the battery's SOC. This feature allows the IC to be located on system side, reducing cost and supply chain constraints on the battery. Measurement and estimated capacity data sets are accessed through an I2C interface. The MAX17040/MAX17041 are available in a small, 2mm x 3mm, 8-pin TDFN lead-free package.
Features
o Host-Side or Battery-Side Fuel Gauging 1 Cell (MAX17040) 2 Cell (MAX17041) o Precision Voltage Measurement 12.5mV Accuracy to 5.00V (MAX17040) 30mV Accuracy to 10.00V (MAX17041) o Accurate Relative Capacity (RSOC) Calculated from ModelGauge Algorithm o o o o o No Offset Accumulation on Measurement No Full-to-Empty Battery Relearning Necessary No Sense Resistor Required 2-Wire Interface Low Power Consumption
MAX17040/MAX17041
o Tiny, Lead-Free, 8-Pin, 2mm x 3mm TDFN Package
Ordering Information
PART MAX17040G+U MAX17040G+T MAX17041G+U TEMP RANGE -20C to +70C -20C to +70C -20C to +70C PIN-PACKAGE 8 TDFN-EP* 8 TDFN-EP* 8 TDFN-EP*
Applications
Smart Phones MP3 Players Digital Still Cameras Digital Video Cameras Portable DVD Players GPS Systems Handheld and Portable Applications
MAX17041G+T -20C to +70C 8 TDFN-EP* +Denotes a lead(Pb)-free/RoHS-compliant package. T =Tape and reel. *EP = Exposed pad.
ModelGauge is a trademark of Maxim Integrated Products, Inc.
Pin Configuration
TOP VIEW
SDA SCL 8 7 EO 6 SEO 5
Simplified Operating Circuit
150 CELL VDD
150 SYSTEM P
MAX17040 MAX17041
Li+ PROTECTION CIRCUIT
MAX17040 MAX17041 SEO
EO CTG GND EP SDA SCL 10nF I2C BUS MASTER
+ 1 2 3 4
CTG CELL VDD GND
1F
TDFN (2mm x 3mm)
________________________________________________________________ Maxim Integrated Products
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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.
Compact, Low-Cost 1S/2S Fuel Gauges MAX17040/MAX17041
ABSOLUTE MAXIMUM RATINGS
Voltage on CTG Pin Relative to VSS .......................-0.3V to +12V Voltage on CELL Pin Relative to VSS ......................-0.3V to +12V Voltage on All Other Pins Relative to VSS .................-0.3V to +6V Operating Temperature Range ...........................-40C to +85C Power Dissipation ..........1333mW at +70C (derate 16.7mW/C) Storage Temperature Range .............................-55C to +125C Lead Temperature (soldering, 10s) .................................+300C Soldering Temperature (reflow) .......................................+260C
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 RECOMMENDED DC OPERATING CONDITIONS
(2.5V VDD 4.5V, TA = -20C to +70C, unless otherwise noted.)
PARAMETER Supply Voltage Data I/O Pins MAX17040 CELL Pin MAX17041 CELL Pin SYMBOL VDD (Note 1) SCL, SDA, (Note 1) EO, SEO VCELL VCELL (Note 1) (Note 1) CONDITIONS MIN +2.5 -0.3 -0.3 -0.3 TYP MAX +4.5 +5.5 +5.0 +10.0 UNITS V V V V
DC ELECTRICAL CHARACTERISTICS
(2.5V VDD 4.5V, TA = -20C to +70C, unless otherwise noted. Contact Maxim for VDD greater than 4.5V.)
PARAMETER Active Current Sleep-Mode Current (Note 2) SYMBOL IACTIVE I SLEEP CONDITIONS With on-chip clock in use With external 32kHz clock VDD = 2.0V VDD = 3.6V at +25C Time-Base Accuracy (Note 3) MAX17040 VoltageMeasurement Error MAX17041 VoltageMeasurement Error CELL Pin Input Impedance Input Logic-High: SCL, SDA, EO, SEO Input Logic-Low: SCL, SDA, EO, SEO Output Logic-Low: SDA Pulldown Current: SCL, SDA Input Capacitance: EO Bus Low Timeout VGERR t ERR TA = 0C to +70C TA = -20C to +70C TA = +25C, VIN = VDD TA = +25C, 5.0V < VIN < 9.0V 5.0 < VIN < 9.0 RCELL VIH VIL VOL I PD CBUS t SLEEP (Note 4) 1.75 (Note 1) (Note 1) I OL = 4mA (Note 1) VDD = 4.5V, VPIN = 0.4V 0.2 50 2.5 -1 -2 -3 -12.5 -30 -30 -60 15 1.4 0.5 0.4 MIN TYP 50 40 0.5 1 MAX 75 65 1.0 3 +1 +2 +3 +12.5 +30 +30 +60 M V V V A pF s mV % UNITS A A
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Compact, Low-Cost 1S/2S Fuel Gauges
ELECTRICAL CHARACTERISTICS: 2-WIRE INTERFACE
(2.5V VDD 4.5V, TA = -20C to +70C.)
PARAMETER SCL Clock Frequency Bus Free Time Between a STOP and START Condition Hold Time (Repeated) START Condition Low Period of SCL Clock High Period of SCL Clock Setup Time for a Repeated START Condition Data Hold Time Data Setup Time Rise Time of Both SDA and SCL Signals Fall Time of Both SDA and SCL Signals Setup Time for STOP Condition Spike Pulse Widths Suppressed by Input Filter Capacitive Load for Each Bus Line SCL, SDA Input Capacitance SYMBOL fSCL tBUF tHD:STA tLOW tHIGH tSU:STA tHD:DAT tSU:DAT tR tF tSU:STO tSP CB CBIN (Note 8) (Note 9) (Notes 6, 7) (Note 6) (Note 5) (Note 5) CONDITIONS MIN 0 1.3 0.6 1.3 0.6 0.6 0 100 20 + 0.1CB 20 + 0.1CB 0.6 0 50 400 60 300 300 0.9 TYP MAX 400 UNITS kHz s s s s s s ns ns ns s ns pF pF
MAX17040/MAX17041
Note 1: All voltages are referenced to VSS. Note 2: SDA, SCL = VSS; EO, SEO idle. Note 3: External time base on EO pin must meet this specification. Note 4: The MAX17040/MAX17041 enter Sleep mode 1.75s to 2.5s after (SCL < VIL) AND (SDA < VIL). Note 5: fSCL must meet the minimum clock low time plus the rise/fall times. Note 6: The maximum tHD:DAT has only to be met if the device does not stretch the low period (tLOW) of the SCL signal. Note 7: This device internally provides a hold time of at least 75ns for the SDA signal (referred to the VIHMIN of the SCL signal) to bridge the undefined region of the falling edge of SCL. Note 8: Filters on SDA and SCL suppress noise spikes at the input buffers and delay the sampling instant. Note 9: CB--total capacitance of one bus line in pF.
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Compact, Low-Cost 1S/2S Fuel Gauges MAX17040/MAX17041
Typical Operating Characteristics
(TA = +25C, unless otherwise noted.)
SIMPLE C/2 RATE CYCLES SOC ACCURACY
100 90 80 STATE OF CHARGE (%) 70 60 50 40 30 20 10 0 0 1 2 VDD (V) 3 4 5 0 0 REFERENCE SOC: SOLID LINE 2 4 6 TIME (hr) 8 ERROR (%) 10 12 MAX17040/ MAX17041 SOC: DASHED LINE
MAX17040 toc02
QUIESCENT CURRENT vs. SUPPLY VOLTAGE
MAX17040 toc01
100
10 8 6 SOC ERROR (%) 4 2 0 -2 -4 -6 -8 -10
QUIESCENT CURRENT (A)
80
TA = +25C
TA = +70C
60
40
20
TA = -20C
SIMPLE C/4 RATE CYCLES SOC ACCURACY
100 90 80 STATE OF CHARGE (%) 70 60 50 40 30 20 10 0 0 2 4 6 8 10 12 14 16 18 20 22 TIME (hr) REFERENCE SOC: SOLID LINE ERROR (%) MAX17040/ MAX17041 SOC: DASHED LINE
MAX17040 toc03
MAX17040 VOLTAGE ADC ERROR vs. TEMPERATURE
8 VOLTAGE ADC ERROR (mV) 6 SOC ERROR (%) 4 2 0 -2 -4 -6 -8 -10 -15 -20 -40 -15 10 35 60 85 TEMPERATURE (C) 15 10 5 0 -5 -10 VCELL = 3.6V VCELL = 3.0V
MAX17040 toc04
10
20 VCELL = 4.2V
C/2 RATE ZIGZAG PATTERN SOC ACCURACY
100 90 80 STATE OF CHARGE (%) 70 60 50 40 30 20 10 0 0 4 8 12 TIME (hr) 16 20 22 REFERENCE SOC: SOLID LINE MAX17040/MAX17041 SOC: DASHED LINE ERROR (%)
MAX17040 toc05
10 8 6 SOC ERROR (%) 4 2 0 -2 -4 -6 -8 -10
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Compact, Low-Cost 1S/2S Fuel Gauges
Pin Description
PIN 1 2 3 4 5 NAME CTG CELL VDD GND SEO FUNCTION Connect to Ground. Connect to VSS during normal operation. Battery Voltage Input. The voltage of the cell pack is measured through this pin. Power-Supply Input. 2.5V to 4.5V input range. Connect to system power through a decoupling network. Connect a 10nF typical decoupling capacitor close to pin. Ground. Connect to the negative power rail of the system. External 32kHz Clocking Signal Enable Input. Input to enable external clocking signal on EO pin with a pullup state. A pulldown state to configure the interrupt feature. External 32kHz clock enable. Connects logic-low to enable external interrupt. External 32kHz Clocking Signal. Input for external clocking signal to be the primary system clock. Configured to implement interrupt feature with a pulldown set on SEO pin. Serial Clock Input. Input only 2-wire clock line. Connect this pin to the CLOCK signal of the 2-wire interface. This pin has a 0.2A typical pulldown to sense disconnection. Serial Data Input/Output. Open-drain 2-wire data line. Connect this pin to the DATA signal of the 2-wire interface. This pin has a 0.2A typical pulldown to sense disconnection. Exposed Pad. Connect PD to ground.
MAX17040/MAX17041
6 7 8 --
EO SCL SDA EP
SDA
tF tLOW tR tSU:DAT
tF tHD:STA
tSP
tR
tBUF
SCL
tHD:STA S tHD:DAT
tSU:STA Sr
tSU:STO P S
Figure 1. 2-Wire Bus Timing Diagram
Detailed Description
VDD BIAS VOLTAGE REFERENCE ADC (VCELL) CELL GND TIME BASE (32kHz) EO
Figure 1 shows the 2-wire bus timing diagram, and Figure 2 is the MAX17040/MAX17041 block diagram.
MAX17040 MAX17041
STATE MACHINE (SOC, RATE)
SEO CTG
ModelGauge Theory of Operation
The MAX17040/MAX17041 use a sophisticated battery model, which determines the SOC of a nonlinear Li+ battery. The model effectively simulates the internal dynamics of a Li+ battery and determines the SOC. The model considers the time effects of a battery caused by the chemical reactions and impedance in the battery. The MAX17040/MAX17041 SOC calculation does not accumulate error with time. This is advantageous
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IC GROUND
2-WIRE INTERFACE
SDA SCL
Figure 2. Block Diagram
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Compact, Low-Cost 1S/2S Fuel Gauges MAX17040/MAX17041
compared to traditional coulomb counters, which suffer from SOC drift caused by current-sense offset and cell self-discharge. This model provides good performance for many Li+ chemistry variants across temperature and age. The MAX17040/MAX17041 have a preloaded ROM table, which provides very good performance for most chemistries.
Quick-Start
A quick-start allows the MAX17040/MAX17041 to restart fuel-gauge calculations in the same manner as initial power-up of the IC. For example, if an application's power-up sequence is exceedingly noisy such that excess error is introduced into the IC's "first guess" of SOC, the host can issue a quick-start to reduce the error. A quick-start is initiated by a rising edge on the EO pin when SEO is logic-low, or through software by writing 4000h to the MODE register.
Fuel-Gauge Performance
The classical coulomb-counter-based fuel gauges suffer from accuracy drift due to the accumulation of the offset error in the current-sense measurement. Although the error is often very small, the error increases over time in such systems, cannot be eliminated, and requires periodic corrections. The corrections are usually performed on a predefined SOC level near full or empty. Some other systems use the relaxed battery voltage to perform corrections. These systems determine the true SOC based on the battery voltage after a long time of no activity. Both have the same limitation: if the correction condition is not observed over time in the actual application, the error in the system is boundless. In some systems, a full charge/discharge cycle is required to eliminate the drift error. To determine the true accuracy of a fuel gauge, as experienced by end users, the battery should be exercised in a dynamic manner. The end-user accuracy cannot be understood with only simple cycles. The MAX17040/MAX17041 do not suffer from the drift problem since they do not rely on the current information.
External Oscillator Control
When the SEO pin is logic-high, the MAX17040/ MAX17041 disable the 32kHz internal oscillator and rely on external clocking from the EO pin. A precision external clock source reduces current consumption during normal operation. When the SEO pin is logic-low, the EO pin becomes an interrupt input. Any rising edge detected on EO causes the MAX17040/MAX17041 to initiate a quick-start.
Sleep Mode
Holding both SDA and SCL logic-low forces the MAX17040/MAX17041 into Sleep mode. While in Sleep mode, all IC operations are halted and power drain of the IC is greatly reduced. After exiting Sleep mode, fuel-gauge operation continues from the point it was halted. SDA and SCL must be held low for at least 2.5s to guarantee transition into Sleep mode. Afterwards, a rising edge on either SDA or SCL immediately transitions the IC out of Sleep mode.
IC Power-Up
When the battery is first inserted into the system, there is no previous knowledge about the battery's SOC. The IC assumes that the battery has been in a relaxed state for the previous 30min. The first A/D voltage measurement is translated into a best "first guess" for the SOC. Initial error caused by the battery not being in a relaxed state fades over time, regardless of cell loading following this initial conversion. Because the SOC determination is convergent rather than divergent (as in a coulomb counter), this initial error does not have a long-lasting impact.
Power-On Reset (POR)
Writing a value of 5400h to the COMMAND register causes the MAX17040/MAX17041 to completely reset as if power had been removed. The reset occurs when the last bit has been clocked in. The IC does not respond with an I2C ACK after this command sequence.
Registers
All host interaction with the MAX17040/MAX17041 is handled by writing to and reading from register locations. The MAX17040/MAX17041 have six 16-bit registers: SOC, VCELL, MODE, VERSION, RCOMP, and COMMAND. Register reads and writes are only valid if all 16 bits are transferred. Any write command that is terminated early is ignored. The function of each register is described as follows. All remaining address locations not listed in Table 1 are reserved. Data read from reserved locations is undefined.
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Compact, Low-Cost 1S/2S Fuel Gauges MAX17040/MAX17041
Table 1. Register Summary
ADDRESS (HEX) 02h-03h 04h-05h 06h-07h 08h-09h 0Ch-0Dh FEh-FFh REGISTER VCELL SOC MODE VERSION RCOMP COMMAND DESCRIPTION Reports 12-bit A/D measurement of battery voltage. Reports 16-bit SOC result calculated by ModelGauge algorithm. Sends special commands to the IC. Returns IC version. Battery compensation. Adjusts IC performance based on application conditions. Sends special commands to the IC. READ/ WRITE R R W R R/W W DEFAULT (HEX) -- -- -- -- 9700h --
VCELL Register
Battery voltage is measured at the CELL pin input with respect to GND over a 0 to 5.00V range for the MAX17040 and 0 to 10.00V for the MAX17041 with resolutions of 1.25mV and 2.50mV, respectively. The A/D calculates the average cell voltage for a period of 125ms after IC POR and then for a period of 500ms for every cycle afterwards. The result is placed in the VCELL register at the end of each conversion period. Figure 3 shows the VCELL register format.
SOC Register
The SOC register is a read-only register that displays the state of charge of the cell as calculated by the ModelGauge algorithm. The result is displayed as a percentage of the cell's full capacity. This register
MSB--ADDRESS 02h 211 MSB 0: BITS ALWAYS READ LOGIC 0 210 29 28 27 26 25 24 LSB
automatically adapts to variation in battery size since the MAX17040/MAX17041 naturally recognize relative SOC. Units of % can be directly determined by observing only the high byte of the SOC register. The low byte provides additional resolution in units 1/256%. The reported SOC also includes residual capacity, which might not be available to the actual application because of early termination voltage requirements. When SOC() = 0, typical applications have no remaining capacity. The first update occurs 125ms after POR of the IC. Subsequent updates occur at variable intervals depending on application conditions. ModelGauge calculations outside the register are clamped at minimum and maximum register limits. Figure 4 shows the SOC register format.
LSB--ADDRESS 03h 23 MSB UNITS: 1.25mV FOR MAX17040 2.50mV FOR MAX17041 22 21 20 0 0 0 0 LSB
Figure 3. VCELL Register Format
MSB--ADDRESS 04h 27 MSB 26 25 24 23 22 21 20 LSB 2-1 MSB 2-2
LSB--ADDRESS 05h 2-3 2-4 2-5 2-6 2-7 2-8 LSB UNITS: 1.0%
Figure 4. SOC Register Format
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Compact, Low-Cost 1S/2S Fuel Gauges MAX17040/MAX17041
MODE Register
The MODE register allows the host processor to send special commands to the IC (Figure 4). Valid MODE register write values are listed as follows. All other MODE register values are reserved. Table 2 shows the MODE register command.
Table 3. COMMAND Register Command
VALUE 5400h COMMAND POR DESCRIPTION See the Power-On Reset (POR) description section.
Table 2. MODE Register Command
VALUE 4000h COMMAND Quick-Start DESCRIPTION See the Quick-Start description section.
Application Examples
The MAX17040/MAX17041 have a variety of configurations, depending on the application. Table 4 shows the most common system configurations and the proper pin connections for each. Figure 5 shows an example application for a 1S cell pack. The MAX17040 is mounted on the system side and powered directly from the cell pack. The external RC networks on VDD and CELL provide noise filtering of the IC power supply and A/D measurement. In this example, the SEO pin is connected to VDD to allow an external clock and reduce power usage by the MAX17040. The system's 32kHz clock is connected to the EO input pin. Figure 6 shows a MAX17041 example application using a 2S cell pack. The MAX17041 is mounted on the system side and powered from a 3.3V supply generated by the system. The CELL pin is still connected directly to PACK+ through an external noise filter. The SEO pin is connected low to allow the system hardware to reset the fuel gauge. After power is supplied, the system watchdog generates a low-to-high transition on the EO pin to signal the MAX17041 to perform a quick-start.
VERSION Register
The VERSION register is a read-only register that contains a value indicating the production version of the MAX17040/MAX17041.
RCOMP Register
RCOMP is a 16-bit value used to compensate the ModelGauge algorithm. RCOMP can be adjusted to optimize performance for different lithium chemistries or different operating temperatures. Contact Maxim for instructions for optimization. The factory-default value for RCOMP is 9700h.
COMMAND Register
The COMMAND register allows the host processor to send special commands to the IC. Valid COMMAND register write values are listed as follows. All other COMMAND register values are reserved. Table 3 shows the COMMAND register command.
Table 4. Possible Application Configurations
SYSTEM CONFIGURATION 1S Pack-Side Location 1S Host-Side Location 1S Host-Side Location, External Clocking 1S Host-Side Location, Hardware Quick-Start 2S Pack-Side Location 2S Host-Side Location 2S Host-Side Location, External Clocking 2S Host-Side Location, Hardware Quick-Start IC MAX17040 MAX17040 MAX17040 MAX17040 MAX17041 MAX17041 MAX17041 MAX17041 VDD Power directly from battery Power directly from battery Power directly from battery Power directly from battery Power from 2.5V to 4.5V LDO in pack Power from 2.5V to 4.5V LDO or PMIC Power from 2.5V to 4.5V LDO or PMIC Power from 2.5V to 4.5V LDO or PMIC SEO Connect to GND Connect to GND Connect to VDD Connect to GND Connect to GND Connect to GND Connect to VDD Connect to GND EO Connect to GND Connect to GND Connect to precision 32kHz clock source Connect to risingedge reset signal Connect to GND Connect to GND Connect to precision 32kHz clock source Connect to risingedge reset signal
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Compact, Low-Cost 1S/2S Fuel Gauges MAX17040/MAX17041
BATTERY PACK+ 150 150 MAX17040 PROTECTION IC (Li+/POLYMER) 1F CELL CTG GND EP SEO VDD EO SDA SCL 10nF SYSTEM VSS PACKSYSTEM P 32kHz OSCILLATOR OUTPUT I2C BUS MASTER SYSTEM SYSTEM VDD
Figure 5. MAX17040 Application Example with External Clock
BATTERY PACK+ 150 MAX17041 PROTECTION IC (Li+/POLYMER) 1F CELL SEO CTG GND EP PACKVDD EO SDA SCL
SYSTEM SYSTEM VDD
SYSTEM PMIC 3.3V OUTPUT WATCHDOG I2C BUS MASTER SYSTEM P SYSTEM VSS
Figure 6. MAX17041 Application Example with Hardware Reset
2-Wire Bus System
The 2-wire bus system supports operation as a slaveonly device in a single or multislave, and single or multimaster system. Slave devices can share the bus by uniquely setting the 7-bit slave address. The 2-wire interface consists of a serial data line (SDA) and serial clock line (SCL). SDA and SCL provide bidirectional communication between the MAX17040/MAX17041 slave device and a master device at speeds up to 400kHz. The MAX17040/MAX17041s' SDA pin operates
bidirectionally; that is, when the MAX17040/MAX17041 receive data, SDA operates as an input, and when the MAX17040/MAX17041 return data, SDA operates as an open-drain output, with the host system providing a resistive pullup. The MAX17040/MAX17041 always operate as a slave device, receiving and transmitting data under the control of a master device. The master initiates all transactions on the bus and generates the SCL signal, as well as the START and STOP bits, which begin and end each transaction.
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Compact, Low-Cost 1S/2S Fuel Gauges MAX17040/MAX17041
Bit Transfer
One data bit is transferred during each SCL clock cycle, with the cycle defined by SCL transitioning low to high and then high to low. The SDA logic level must remain stable during the high period of the SCL clock pulse. Any change in SDA when SCL is high is interpreted as a START or STOP control signal.
Data Order
A byte of data consists of 8 bits ordered most significant bit (MSb) first. The least significant bit (LSb) of each byte is followed by the Acknowledge bit. The MAX17040/MAX17041 registers composed of multibyte values are ordered MSB first. The MSB of multibyte registers is stored on even data-memory addresses.
Bus Idle
The bus is defined to be idle, or not busy, when no master device has control. Both SDA and SCL remain high when the bus is idle. The STOP condition is the proper method to return the bus to the idle state.
Slave Address
A bus master initiates communication with a slave device by issuing a START condition followed by a Slave Address (SAddr) and the Read/Write (R/W) bit. When the bus is idle, the MAX17040/MAX17041 continuously monitor for a START condition followed by its Slave Address. When the MAX17040/MAX17041 receive a Slave Address that matches the value in the Slave Address Register, it responds with an Acknowledge bit during the clock period following the R/W bit. The 7-bit slave address is fixed to 6Ch (write)/ 6DH (read):
MAX17040/MAX17041 SLAVE ADDRESS 0110110
START and STOP Conditions
The master initiates transactions with a START condition (S) by forcing a high-to-low transition on SDA while SCL is high. The master terminates a transaction with a STOP condition (P), a low-to-high transition on SDA while SCL is high. A Repeated START condition (Sr) can be used in place of a STOP then START sequence to terminate one transaction and begin another without returning the bus to the idle state. In multimaster systems, a Repeated START allows the master to retain control of the bus. The START and STOP conditions are the only bus activities in which the SDA transitions when SCL is high.
Read/Write Bit
The R/W bit following the slave address determines the data direction of subsequent bytes in the transfer. R/W = 0 selects a write transaction, with the following bytes being written by the master to the slave. R/W = 1 selects a read transaction, with the following bytes being read from the slave by the master.
Acknowledge Bits
Each byte of a data transfer is acknowledged with an Acknowledge bit (A) or a No-Acknowledge bit (N). Both the master and the MAX17040 slave generate acknowledge bits. To generate an acknowledge, the receiving device must pull SDA low before the rising edge of the acknowledge-related clock pulse (ninth pulse) and keep it low until SCL returns low. To generate a no acknowledge (also called NAK), the receiver releases SDA before the rising edge of the acknowledge-related clock pulse and leaves SDA high until SCL returns low. Monitoring the Acknowledge bits allows for detection of unsuccessful data transfers. An unsuccessful data transfer can occur if a receiving device is busy or if a system fault has occurred. In the event of an unsuccessful data transfer, the bus master should reattempt communication.
Bus Timing
The MAX17040/MAX17041 are compatible with any bus timing up to 400kHz. No special configuration is required to operate at any speed.
2-Wire Command Protocols
The command protocols involve several transaction formats. The simplest format consists of the master writing the START bit, slave address, R/W bit, and then monitoring the Acknowledge bit for presence of the MAX17040/ MAX17041. More complex formats, such as the Write Data and Read Data, read data and execute device-specific operations. All bytes in each command format require the slave or host to return an Acknowledge bit before continuing with the next byte. Table 5 shows the key that applies to the transaction formats.
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Compact, Low-Cost 1S/2S Fuel Gauges
Table 5. 2-Wire Protocol Key
KEY S SAddr MAddr Data A N START bit Slave address (7 bit) Memory address byte Data byte written by master Acknowledge bit--master No acknowledge--master DESCRIPTION Sr W P Data A N KEY Repeated START R/W bit = 0 STOP bit Data byte returned by slave Acknowledge bit--slave No acknowledge--slave DESCRIPTION
MAX17040/MAX17041
Basic Transaction Formats
Write: S. SAddr W. A. MAddr. A. Data0. A. Data1. A. P A write transaction transfers 2 or more data bytes to the MAX17040/MAX17041. The data transfer begins at the memory address supplied in the MAddr byte. Control of the SDA signal is retained by the master throughout the transaction, except for the acknowledge cycles:
Read: S. SAddr W. A. MAddr. A. Sr. SAddr R. A. Data0. A. Data1. N. P Write Portion Read Portion
A read transaction transfers 2 or more bytes from the MAX17040/MAX17041. Read transactions are composed of two parts, a write portion followed by a read portion, and are therefore inherently longer than a write transaction. The write portion communicates the starting point for the read operation. The read portion follows immediately, beginning with a Repeated START, Slave Address with R/W set to a 1. Control of SDA is assumed by the MAX17040/MAX17041, beginning with the Slave Address Acknowledge cycle. Control of the SDA signal is retained by the MAX17040/MAX17041 throughout the transaction, except for the acknowledge cycles. The master indicates the end of a read transaction by responding to the last byte it requires with a no acknowledge. This signals the MAX17040/MAX17041 that control of SDA is to remain with the master following the acknowledge clock.
The MSB of the data to be stored at address MAddr can be written immediately after the MAddr byte is acknowledged. Because the address is automatically incremented after the LSB of each byte is received by the MAX17040/MAX17041, the MSB of the data at address MAddr + 1 can be written immediately after the acknowledgment of the data at address MAddr. If the bus master continues an autoincremented write transaction beyond address 4Fh, the MAX17040/ MAX17041 ignore the data. A valid write must include both register bytes. Data is also ignored on writes to read-only addresses. Incomplete bytes and bytes that are not acknowledged by the MAX17040/MAX17041 are not written to memory.
Read Data Protocol
The read data protocol is used to read to register from the MAX17040/MAX17041 starting at the memory address specified by MAddr. Both register bytes must be read in the same transaction for the register data to be valid. Data0 represents the data byte in memory location MAddr, Data1 represents the data from MAddr + 1, and DataN represents the last byte read by the master: S. SAddr W. A. MAddr. A. Sr. SAddr R. A. Data0. A. Data1. A... DataN. N. P Data is returned beginning with the MSB of the data in MAddr. Because the address is automatically incremented after the LSB of each byte is returned, the MSB of the data at address MAddr + 1 is available to the host immediately after the acknowledgment of the data at address MAddr. If the bus master continues to read beyond address FFh, the MAX17040/MAX17041 output data values of FFh. Addresses labeled Reserved in the memory map return undefined data. The bus master terminates the read transaction at any byte boundary by issuing a no acknowledge followed by a STOP or Repeated START.
Write Data Protocol
The write data protocol is used to write to register to the MAX17040/MAX17041 starting at memory address MAddr. Data0 represents the data written to MAddr, Data1 represents the data written to MAddr + 1, and DataN represents the last data byte, written to MAddr + N. The master indicates the end of a write transaction by sending a STOP or Repeated START after receiving the last Acknowledge bit: SAddr W. A. MAddr. A. Data0. A. Data1. A... DataN. A
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11
Compact, Low-Cost 1S/2S Fuel Gauges MAX17040/MAX17041
Package Information
For the latest package outline information and land patterns, go to www.maxim-ic.com/packages. PACKAGE TYPE 8 TDFN PACKAGE CODE T823+1 DOCUMENT NO. 21-0174
12
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Compact, Low-Cost 1S/2S Fuel Gauges
Revision History
REVISION NUMBER 0 REVISION DATE 7/08 Initial release * Corrected the order of the pins in the Pin Configuration * Changed the max operating voltage from 5.5V to 4.5V * Inserted the "CELL Pin Input Impedance" specification into the DC Electrical Characteristics table * Corrected the order of the pins in the Pin Description table and changed the max operating voltage for the VDD pin * Added the following sentence to the Registers section: "Register reads and writes are only valid if all 16 bits are transferred" * Added the following sentence to the Write Data Protocol section: "A valid write must include both register bytes" * Added the following sentence to the Read Data Protocol section: "Both register bytes must be read in the same transaction for the register data to be valid" Exposed pad connection to ground in Figures 5 and 6; corrected errors in specifications DESCRIPTION PAGES CHANGED --
MAX17040/MAX17041
1
10/08
1, 2, 3, 5, 8
2
3/09
6, 11
3
4/10
1, 2, 7, 9, 13
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 ____________________ 13
(c) 2010 Maxim Integrated Products Maxim is a registered trademark of Maxim Integrated Products, Inc.


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