XR18910IL-65

XR18910 8:1 Sensor Interface Analog Front End Description FEATURES ■■ Integrated features for interfacing multiple bridge sensors with an MCU or FPGA 8:1 differential MUX with I2C interface Instrumentation amplifier LDO Offset correction DAC with I2C interface (±560mV offset correction range) ■■ Eight selectable voltage gains from 2V/V to 760V/V with only ±0.5% gain error ■■ 3mV maximum input offset voltage ■■ 100pA maximum input bias current ■■ 559μA maximum supply current ■■ 2.7V to 5V analog supply voltage range ■■ 1.8V to 5V digital supply voltage range ■■ -40°C to 85°C temperature range ■■ 3.5mm x 3.5mm TQFN-24 package The XR18910 is a unique sensor interface integrated circuit with an onboard 8:1 multiplexer, offset correction Digital-to-Analog Converter (DAC), instrumentation amplifier and voltage reference. The XR18910 is designed to integrate multiple bridge sensors with a Microcontroller (MCU) or Field-Programmable Gate Array (FPGA). The integrated offset correction DAC provides digital calibration of the variable and in many cases substantial offset voltage generated by the bridge sensors. The DAC is controlled by an I2C compatible 2-wire serial interface. The serial interface also provides the user with easy controls to the XR18910’s many functions such as input and gain selection. A linear regulator (LDO) provides a regulated voltage to power the input bridge sensors and is selectable, between 3V and 2.65V. The LDO current can be sensed and a proportional voltage present at the output of the IC for monitoring the LDO current. The XR18910 offers 8 fixed gain settings (from 2V/V to 760V/V), each with an error of only ±0.5%, that are selectable via the I2C interface. It also offers less than 3mV maximum input offset voltage, 100pA maximum input bias current, and 100pA maximum input offset current. APPLICATIONS ■■ Bridge sensor interface ■■ Pressure and temperature sensors ■■ Strain gauge amplifier ■■ Industrial process controls ■■ Weigh scales The XR18910 is designed to operate from 2.7V to 5V supplies, specified over the industrial temperature range of -40°C to 85°C and is offered in a space saving 3.5mm x 3.5mm TQFN package. It consumes less than 559μA supply current and offers a sleep mode for added power savings. The XR18910 is well suited for industrial and consumer applications using bridge sensors. Typical Application VDD VCC 6.8μF 6.8μF + + BRDG 2.5 0.1μF 0.1μF VCC 2 VDD 1.5 0.1μF BRIDGE 8 IN8- INA / PGA 8:1 MUX BRIDGE 1 10k ADC µC 10nF ±560mV OFFSET TRIM VDD 10-BIT DAC PGA IN1+ IN1- OUT 4.7k VDD 1 0.5 0 -0.5 -1 -1.5 -2 4.7k SDA -2.5 I2C CONTROL RTI Noise (µV) LDO IN8+ SCL 0 2 4 6 Time (seconds) 8 10 XR18910 AGND DGND Figure 1. Typical Application Figure 2. 0.1Hz to 10Hz RTI Voltage Noise Rev1C 1/20 XR18910 Absolute Maximum Ratings Operating Conditions Stresses beyond the limits listed below may cause permanent damage to the device. Exposure to any Absolute Maximum Rating condition for extended periods may affect device reliability and lifetime. Analog supply voltage range..................................... 2.7V to 5.25V Analog supply voltage (VCC)........................................... 0V to 5.5V Digital supply voltage (VDD)............................................ 0V to 5.5V Digital input/output (VDDIO)............................................. 0V to 5.5V VIN......................................................................................0 to VCC Differential input voltage (current limit of 10mA)....................... VCC Digital supply voltage range........................................1.7V to 5.25V Operating temperature range....................................-40°C to 85°C Junction temperature............................................................. 150°C Storage temperature range......................................-65°C to 150°C Lead temperature (soldering, 10s).........................................260°C Package thermal resistance θJA.......................................50°C/W(1) NOTE: 1. JEDEC standard, multi-layer test boards, still air. ESD rating (HBM - human body model)....................................4kV Rev1C 2/20 XR18910 Electrical Characteristics TA = 25°C, VCC = 3.3V, VDD = 1.8V, RL = 10kΩ to 1.5V, G = 760, unless otherwise noted. Symbol Parameter Conditions Min Typ Max Input referred -3 ±0.02 3 Units DC Performance VIO Input offset voltage dVIO Input offset voltage average drift IB Input bias current IOS Input offset current PSRR Power supply rejection ratio G GE 3 15 100 pA -100 1 100 pA 60 91 dB Gain = 2 2.0 V/V Gain = 20 20.0 V/V Gain = 40 40.0 V/V Gain = 80 80.0 V/V 150.0 V/V Gain = 300 299.9 V/V Gain = 600 599.6 V/V Gain = 760 759.4 V/V Gain = 150 -100 mV μV/°C VCC = 2.7V to 5V Nominal, refer to Gain Register Table (pg. 8) Gain error -0.5 Gain error vs temperature 0.5 ±10 % ppm/°C ISVCC VCC supply current No load to output, no load to LDO 435 530 μA ISVCCD Disable VCC supply current No load to output, no load to LDO 48 62 μA ISVDD VDD supply current No load to output, no load to LDO, I2C running 22 29 μA ISTOTAL Total supply current No load to output, no load to LDO 457 559 μA ISDTOTAL Total disable supply current No load to output, no load to LDO, LDO DIS 45 No load to output, no load to LDO, LDO EN 70 μA 91 μA Input Characteristics Input impedance CMIR Common mode input range CMRR Common mode rejection ratio Ω || pF 1013 || 11.2 0.5 0.23 to 3.06 Input referred, VCM = 0.5 to 2.0V 75 88 2.5 V dB Output Characteristics VOUT Output voltage swing RL = 10kΩ to 1.5V 0.1 0.04 to 3.29 3.1 V VOO Output offset Offset DAC 0 00 0000 0000, G = 2 1.4 1.5 1.6 V Offset DAC Offset DAC range RTI (referred to input) Offset monotonicity ±560 8 mV 10 Bits LDO Output voltage Dropout voltage 1.5k load, LDO bit LOW -6% 3 +6% V 1.5k load, LDO bit HIGH -6% 2.65 +6% V 150 mV VCC = 2.8V, LDO = 2.65V, ILOAD = 10mA Output current Power supply rejection ratio 10 25 mA Output referred, VCC = 3V to 5V, LDO = 2.65V 45 63 dB Output referred, VCC = 3.3V to 5V, LDO = 3V 45 63 dB 0.08 0.1 Output current sense transimpedance slope Output voltage relative to 1.5V / LDO current, G = 2 Output current sense range clip G=2 18.8 Rev1C 0.12 V/mA mA 3/20 XR18910 Electrical Characteristics (Continued) TA = 25°C, VCC = 3.3V, VDD = 1.8V, RL = 10kΩ to 1.5V, G = 760, unless otherwise noted. Symbol Parameter Conditions Min Typ Max Units Dynamic Performance BW -3dB bandwidth SR Slew rate eNI Input voltage noise, RTI G = 760 66 kHz 1300 kHz VOUT = 1VP-P, G = 2 1 V/μs f = 10Hz 75 nV/√Hz f = 100Hz 46 nV/√Hz f = 1kHz 35 nV/√Hz G=2 iN Input current noise f = 10Hz 0.6 fA/√Hz eNP-P Peak-to-peak noise f = 0.1 to 10Hz 2 μVP-P XTALK Crosstalk Channel-to-channel, f = 1kHz 90 dB TS Set-up time, 1% settling Analog ready after serial register finished write 3.5 μs TWAKE Wake up time, 1% settling Wake from ACK of SLEEP_OUT command 9.6 μs Digital Characteristics (CMOS) Max Units VIH Symbol Logic input HIGH Parameter Conditions 0.7 x VDD Min Typ VDD V VIL Logic input LOW 0 0.3 x VDD V IIH Input leakage HIGH VI = VS 10 μA IIL Input leakage LOW VI = 0 CLKF Clock rate 0.4 MHz -10 μA I2C Bus Timing TA = -40 to 85°C, VDD = 1.8 to 5V, unless otherwise noted. Symbol Parameter Standard Mode I2C-BUS Fast Mode I2C-BUS Min Max Min Max 0 100 0 400 Units fSCL Operating frequency TBUF Bus free time between STOP and START 4.7 1.3 μs THD;STA START condition hold time 4.0 0.6 μs TSU;STA START condition setup time 4.7 0.6 μs THD;DAT Data hold time 0 0 μs TVD;ACK Data valid acknowledge TVD;DAT SCL LOW to data out valid TSU;DAT Data setup time 250 150 ns TLOW Clock LOW period 4.7 1.3 μs THIGH Clock HIGH period 4.0 TF Clock/data fall time 300 300 ns TR Clock/data rise time 1000 300 ns TSP Pulse width of spikes tolerance 0.6 0.6 0.6 μs 0.6 ns 0.6 0.5 0.5 Rev1C kHz μs μs 4/20 XR20M1280 XR18910 I2C/SPI UART WITH 128-BYTE FIFO AND INTEGRATED LEVEL SHIFTERS REV. 1.0.0 Electrical Characteristics (Continued) FIGURE 22. I2C-BUS TIMING DIAGRAM START condition (S) Protocol T SU;STA Bit 7 MSB (A7) T LOW Bit 0 LSB (R/W) Bit 6 (A6) T HIGH Acknowledge (A) STOP condition (P) 1/F SCL SCL TF TR T BUF T SP SDA T HD;STA T SU;DAT T HD;DAT T VD;DAT T VD;ACK T SU;STO Figure 3. I2C Bus Timing Diagram FIGURE 23. WRITE TO OUTPUT SDA SLAVE ADDRESS W A GPIOLVL REG. A DATA A T D1 GPIOn Rev1C 5/20 XR18910 Electrical Characteristics (Continued) Table 1. Register List Reg No. R/ W/ C Byte of Parameter No operation C 0 N/A Does not execute a function. NOP is used to test successful I2C communication SW_RESET Software reset C 0 N/A Resets all registers to default values Name Hex Dec 0x00 0 NOP 1 Function Parameter Default Code Power-up Condition Remark Reset 0x01 Read ID 0x02 2 DEVICE_ID Read Device ID R 2 [15:0]: report “8910” in BCD 0x03 3 VERSION_ID Read HW & SW version numbers R 2 [15:12]: reserved [11:8]: Hardware version # [7:0]: Software version # SLEEP_OUT _REG Normal operating mode, system active C 0 Instructs the XR18910 to report its device ID 8910 in binary form (1000 1001 0001 0000) 0x8910 N/A Initial H/W version number is ‘0’; Initial S/W version number is ‘01’. Sleep in/out 0x04 0x05 4 5 SLEEP_IN _REG Sleep Mode C 0 Gain Gain select R/W 1 Active Puts the XR18910 into active mode. (wake up) N/A Active Puts the analog portion of the XR18910 into sleep mode. During sleep mode, the only I2C command that can be received/ processed is the SLEEP_OUT command (0x04). All other register addresses will be ignored. 0x00 Gain =2 Eight gain settings are selectable (from 2V/V to 760V/V), refer to the Gain Register Table for more information. LDO = 3V Bit 0 controls the LDO voltage (0: 3V; 1: 2.65V). Bit 1 (Sleep Mode only). Bit 1 controls whether the LDO shuts down or stays on during Sleep Mode. (0: Enable; 1: Disable). When the XR18910 is active, the LDO is always on. Off When on, the LDO current is sensed and a proportional voltage is present at the output of the XR18910. Current Sense Mode remains active until an input select command is received by the XR18910. N/A Basic Config 0x06 6 [2:0]: Gain select [0]:LDO 3V, 2.65V 0x07 0x08 7 8 LDO LDO Current Sense Select LDO Settings LDO Current Sense R/W 1 C 0 [1]:LDO disable 0x00 N/A Channel Switch (Input MUX Select) 0x10 16 Select_ Input_1 Select Channel 1 C 0 Select +IN1, -IN1; Channel 1 0x12 18 Select_ Input_2 Select Channel 2 C 0 Select +IN2, -IN2; Channel 2 0x14 20 Select_ Input_3 Select Channel 3 C 0 Select +IN3, -IN3; Channel 3 0x15 21 Select_ Input_4 Select Channel 4 C 0 0x18 24 Select_ Input_5 Select Channel 5 C 0 0x1A 26 Select_ Input_6 Select Channel 6 C 0 Select +IN6, -IN6; Channel 6 0x1C 28 Select_ Input_7 Select Channel 7 C 0 Select +IN7, -IN7; Channel 7 0x1E 30 Select_ Input_8 Select Channel 8 C 0 Select +IN8, -IN8; Channel 8 N/A Rev1C Channel 1 is selected Select +IN4, -IN4; Channel 4 Select +IN5, -IN5; Channel 5 6/20 XR18910 Reg No. Hex Dec Name Function R/ W/ C Byte of Parameter Parameter Default Code Power-up Condition 0x00 0mV offset Remark Offset DAC Config 0x20 32 DAC1 Configures DAC offset applied to Channel 1 R/W 2 0x22 34 DAC2 Configures DAC offset applied to Channel 2 R/W 2 0x24 36 DAC3 Configures DAC offset applied to Channel 3 R/W 2 0x25 37 DAC4 Configures DAC offset applied to Channel 4 R/W 2 [10]: DAC Sign [9:0]: DAC Range 0x28 40 DAC5 Configures DAC offset applied to Channel 5 R/W 2 0x2A 42 DAC6 Configures DAC offset applied to Channel 6 R/W 2 0x2C 44 DAC7 Configures DAC offset applied to Channel 7 R/W 2 0x2E 46 DAC8 Configures DAC offset applied to Channel 8 R/W 2 Bit 10 controls the sign of the DAC offset voltage. Bits 9 thru 0 control the value of the DAC offset voltage. [10]: DAC Sign 0 = positive; 1 = negative NOTE: Register numbers not listed above have no function. Table 2. DAC Registers Hex D10 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 Offset % of FS Input Voltage RTI 0x3FF 0 1 1 1 1 1 1 1 1 1 1 50 560mV 0x000 0 0 0 0 0 0 0 0 0 0 0 0 0 0x7FF 1 1 1 1 1 1 1 1 1 1 1 -50 -560mV 0x400 1 0 0 0 0 0 0 0 0 0 0 0 0 DAC Sign 10-Bit DAC Range Table 3. Gain Registers Hex D2 D1 D0 Gain 0x00 0 0 0 2 0x01 0 0 1 20 0x02 0 1 0 40 0x03 0 1 1 80 0x04 1 0 0 150 0x05 1 0 1 300 0x06 1 1 0 600 0x07 1 1 1 760 Rev1C 7/20 XR18910 SDA SCL DGND VCC OUT AGND 24 23 22 21 20 19 Pin Configuration IN2+ 4 15 IN7- IN2- 5 14 IN7+ IN3+ 6 13 IN6- NOTE: MaxLinear recommends grounding the exposed pad. 12 IN8+ IN6+ 16 11 3 IN5- IN1- 10 IN8- IN5+ 17 9 2 IN4- IN1+ 8 BRDG IN4+ 18 7 1 IN3- VDD Pin Functions Pin Number Pin Name Description 1 VDD Digital Supply 2 IN1+ Positive Input 1 3 IN1- Negative Input 1 4 IN2+ Positive Input 2 5 IN2- Negative Input 2 6 IN3+ Positive Input 3 7 IN3- Negative Input 3 8 IN4+ Positive Input 4 9 IN4- Negative Input 4 10 IN5+ Positive Input 5 11 IN5- Negative Input 5 12 IN6+ Positive Input 6 13 IN6- Negative Input 6 14 IN7+ Positive Input 7 15 IN7- Negative Input 7 16 IN8+ Positive Input 8 17 IN8- Negative Input 8 18 BRDG BRDG Power Connection (LDO output) 19 AGND Analog Ground 20 OUT Output 21 VCC Analog Supply 22 DGND Digital Ground 23 SCL Serial Clock Input 24 SDA Serial Data Input/Output Rev1C 8/20 XR18910 Typical Performance Characteristics TA = 25°C, VCC = 3.3V, VDD = 1.8V, RL = 10kΩ to 1.5V, G = 760, unless otherwise noted. 2 3 G = 2, VOUT = 0.5VP-P 2.5 Output Voltage (V) 1.75 Output Voltage (V) G = 2, VOUT = 2.5VP-P 1.5 1.25 2 1.5 1 0.5 1 0 10 20 30 0 40 0 10 20 Time (µs) Figure 4. Small Signal Pulse Response at G = 2 40 Figure 5. Large Signal Pulse Response at G = 2 2 G = 300, VOUT = 2.5VP-P 3 G = 300, VOUT = 0.5VP-P 2.5 1.75 Output Voltage (V) Output Voltage (V) 30 Time (µs) 1.5 1.25 2 1.5 1 0.5 1 0 20 40 60 80 0 100 0 20 40 Figure 6. Small Signal Pulse Response at G = 300 3 Normalized Gain (dB) Normalized Gain (dB) 0 -3 VOUT = 0.5VP-P VOUT = 1VP-P -9 -12 VOUT = 2.5VP-P 1 10 100 Frequency (kHz) 1000 10000 G = 300 0 -3 -6 VOUT = 0.5VP-P VOUT = 1VP-P VOUT = 2.5VP-P -9 -12 0.1 100 Figure 7. Large Signal Pulse Response at G = 300 G= 2 -6 80 Time (µs) Time (µs) 3 60 0.1 1 10 100 1000 10000 Frequency (kHz) Figure 8. Frequency Response at G = 2 Figure 9. Frequency Response at G = 300 Rev1C 9/20 XR18910 Typical Performance Characteristics (Continued) TA = 25°C, VCC = 3.3V, VDD = 1.8V, RL = 10kΩ to 1.5V, G = 760, unless otherwise noted. 3.5 4 G= 2 Current Sense Mode Active 3 VLDO (V) Output Voltage (V) 3 2.5 2 VCC = 3.3V 1.5 VCC = 5V 1 2 0 5 10 15 20 0 25 0 10 20 ILDO (mA) Figure 10. LDO Current vs. Output Voltage 5 1.5 3 Output Voltage (V) Output Voltage (V) 50 1.55 G= 2 2 1 0 -10 -5 0 5 1.45 G= 2 1.35 10 G = 300 1.4 G = 760 0.25 0.75 1.25 1.75 2.25 2.75 Input Common Mode Voltage (V) Output Current (mA) Figure 12. Output Offset Voltage vs. Output Current Figure 13. Output Offset vs. Input Common Mode Voltage 2.5 100 90 2 G = 760 1.5 80 70 RTI Noise (µV) Input Voltage Noise (nV/√Hz) 40 Figure 11. LDO Output Current 4 -1 30 ILDO (mA) 60 50 40 30 20 1 0.5 0 -0.5 -1 -1.5 10 -2 0 -2.5 0.01 0.1 1 10 100 1000 Frequency (kHz) Figure 14. Input Voltage Noise vs. Frequency 0 2 4 6 Time (seconds) 8 10 Figure 15. 0.1Hz to 10Hz RTI Voltage Noise Rev1C 10/20 XR18910 Typical Performance Characteristics (Continued) TA = 25°C, VCC = 3.3V, VDD = 1.8V, RL = 10kΩ to 1.5V, G = 760, unless otherwise noted. 4 G= 2 Stop Time = 1% Settling Output Voltage (V) 2 3.5 1.5 DUT Output 1 SDA 0.5 3 Output Voltage (V) 2.5 2.5 2 1 5 10 Start Time = 50% Acknowledge 0.5 Start Time = 50% Acknowledge 0 DUT Output 1.5 0 -0.5 Stop Time = 1% Settling SDA 15 0 20 0 5 Time (µs) Figure 16. Sleep to Wake Time (DUT Output) 3.5 3.5 3 Output Voltage (V) Output Voltage (V) SDA 2.5 2 1.5 LDO Output 1 Stop Time = 1% Settling 0.5 0 -0.5 50 100 150 20 2.5 LDO Output Stop Time = 1% Settling 2 1.5 1 SDA 0.5 0 Start Time = 50% Acknowledge 0 15 Figure 17. Set-up Time - from G = 2 to G = 300 (DUT Output) 4 3 10 Time (µs) 200 -0.5 250 Time (µs) Figure 18. LDO Enable to Disable Time Start Time = 50% Acknowledge 0 10 20 30 Time (µs) 40 50 Figure 19. LDO Disable to Enable Time Rev1C 11/20 XR18910 Functional Block Diagram VCC LDO Output 1.5V Reference LDO Enable LDO Select ( 3V, 2.65V ) AGND PGA VDD SDA SCL 2:1 Differential MUX LDO Select Gain Select LDO Enable 10-Bit Offset DAC Power Down Analog Offset - Offset + Output DAC [0:9], Sign Input [0:3] Input 8 +/- Current Sense Mode Input 2 +/- 8:1 Differential MUX Input 1 +/- I2C Serial Digital Interface DGND Figure 20. Functional Block Diagram Application Information The XR18910 sensor interface includes a 8:1 differential multiplexer (MUX), a programmable gain instrumentation amplifier, a 10-bit offset correction DAC and an LDO. An I2C interface controls the many functions and features of the XR18910. The XR18910 is designed to integrate multiple bridge sensors with an ADC/MCU or FPGA. The XR18910 also provides the ability to monitor the LDO current. When the XR18910 is in current sense mode, an internal 2:1 MUX allows a voltage proportional to the LDO current to be present at the output. Once all channels have been calibrated, the LDO current can be used to indirectly monitor any voltage or resistive changes seen by the inputs. Each bridge sensor connected to the XR18910 has its own inherent offset that if not calibrated out can decrease sensitivity and overall performance of the sensor system. The on-board DAC introduces an offset into the instrumentation amplifier to calibrate the offset voltage generated by the sensors. An independent offset can be set for each of the 8 channels. Only the offset voltage of the active channel is applied to the PGA. The XR18910 also includes an internal 1.5V reference that is used by the internal LDO circuitry and used to set the reference voltage for the programmable gain instrumentation amplifier. The programmable gain instrumentation amplifier offers 8 selectable gains from 2V/V to 760V/V to amplify the signal such that it falls within the input range of the ADC. An integrated LDO provides a regulated voltage to power the input bridge sensors and is selectable, between 3V and 2.65V. The LDO can be set to turn off when the XR18910 is in sleep mode to save power. Rev1C During sleep mode, the analog components of the XR18910 are powered down for added power savings. The XR18910 offers many functions, each controlled by the I2C compatible serial interface: ■■ ■■ ■■ ■■ ■■ ■■ Input Selection Gain Selection Offset Correction LDO Enable/Select Current Sense Mode Sleep Mode (analog power down) 12/20 XR18910 Application Information (Continued) Power Up After initial system power up, the I2C master must provide one SCL clock pulse prior to the first I2C access (first start condition). The first access to the XR18910 must be a RESET command. SDA XR20M1280 REV. 1.0.0 I2C/SPI UART WITH 128-BYTE FIFO AND INTEGRATED LEVEL SHIFTERS SCL 1.0 FUNCTIONAL DESCRIPTIONS 1.1 CPU Interface 2 The XR20M1280 can operate with either an I2C-bus interface or an SPI interface. The CPU interface is selected via the I2C/SPI# input pin. I2C-bus Interface I C Bus Interface 2 interface is compliant with the Standard-mode and Fast-mode I2C-bus specifications. The I2C-bus The I2C-bus The I C-bus interface consists of two lines: serial data (SDA) interface consists of two lines: serial data (SDA) and serial clock (SCL). In the Standard-mode, the serial clock and serialserial data can go up to 100 kbps and inThe the Fast-mode, the serial works clock and serial can go upand to 400 and clock (SCL). XR18910 as data a slave kbps. The first byte sent by an I2C-bus master contains a start bit (SDA transition from HIGH to LOW when supports both standard mode rates (100 kbps) and SCL is HIGH), 7-bit slave address and whether it is a transfer read or write transaction. The next byte is the subaddress that contains the address of the register to access. The XR20M1280 responds to each write with 2 an fast mode transfer rates (400 kbps) asSCL defined the acknowledge (SDA driven LOW by XR20M1280 for one clock cycle when is HIGH). Ifin the TX FIFOI isCfull, 2 acknowledge (SDA driven HIGH by XR20M1280 for one clock the XR20M1280 will respond with a negative Bus specification. The I C-bus interface follows all standard cycle when SCL is HIGH) when the CPU tries to write to the TX FIFO. The last byte sent by an I2C-bus master contains a stop bit (SDA transition from LOW to HIGH when SCL is is HIGH). See Figuresbelow, 3 - 5 below.for For I2C protocols. Some information provided complete details, see the I2C-bus specifications. additional information, refer to the I2C-bus specifications. FIGURE 3. Stop Condition To signal the end of the data transfer, the master generates a stop condition by pulling the SDA line from low to high while the SCL line is high, as shown in Figure 22. Figures 23 and 24 illustrate a write and a read cycle. For complete details, see the I2C-bus specifications. Figure 21. I C Power Up 2 1.1.1 I 2C sub-address contains the address of the register to access. The XR18910 Register List is shown in Table 1. Depending on the register accessed, there will be up to two additional data bytes transmitted by the master. Refer to the “Byte of Parameter” column in the Register Table. The XR18910 will respond to each write with an acknowledge. START AND STOP CONDITIONS S SLAVE ADDRESS W A REGISTER ADDRESS A nDATA A P NOTES: White Block = host to XR18910, Orange Block = XR18910 to host. Figure 23. Master Writes to Slave (XR18910) SLAVE REGISTER SLAVE LAST S ADDRESS W A ADDRESS A S ADDRESS R A nDATA A DATA NA P NOTES: White Block = host to XR18910, Orange Block = XR18910 to host. SDA Figure 24. Master Reads from Slave (XR18910) SCL S P START condition STOP condition I2C Bus Addressing The XR18910 uses a 7-bit I2C address. For the standard XR18910, the default address is 0x67 (110 0111). There are three alternative addresses available to help insure that the XR18910 can be identified from the other devices on the I2C-bus. Table 4 shows the different addresses that are available. Figure 22. I2C Start and Stop Conditions FIGURE 4. MASTER WRITES TO SLAVE (XR20M1280) SLAVE ADDRESS S W REGISTER ADDRESS A A nDATA A P The basic I2C access cycle for the XR18910 consists of: White block: host to UART Grey block: UART to host A start condition A slave address cycle ■■ Zero, one, or two data cycles - depending on the XR18910 FIGURE 5. MASTER READS FROM SLAVE (XR20M1280) register accessed ■■ A stop condition ■■ ■■ S SLAVE ADDRESS W A REGISTER ADDRESS A S SLAVE ADDRESS R A nDATA A LAST DATA Table 4. XR18910 I2C Address Map NA P White block: host to UART Grey block: UART to host Start Condition The master initiates data transfer by generating a start condition. The start condition is when a high-to-low transition occurs on the SDA line while SCL is high, as shown in 7 Figure 22. Slave Address Cycle After the start condition, the first byte sent by the master is the 7-bit address and the read/write direction bit R/W on the SDA line. If the address matches the XR18910’s internal fixed address, the XR18910 will respond with an acknowledge by pulling the SDA line low for one clock cycle while SCL is high. Data Cycle After the master detects this acknowledge, the next byte transmitted by the master is the sub-address. This 8-bit Rev1C I2C Address Orderable Part Number 0x67 XR18910ILTR-67 0x66 XR18910ILMTR-66 0x65 XR18910ILMTR-65 0x64 XR18910ILMTR-64 A read or write transaction is determined by the bit immediately following the I2C slave address. If this bit is ‘0’, then it is a write transaction. If this bit is a ‘1’, then it is a read transaction. An I2C sub-address is sent by the I2C master following the slave address. The sub-address contains the XR18910 register address being accessed. Table 1 illustrates the available XR18910 register addresses. After the last read or write transaction, the I2C-bus master will set the SCL signal back to its idle state (HIGH). 13/20 XR18910 Application Information (Continued) Inputs and Input Selection The XR18910 includes 8 differential inputs and a 8:1 differential MUX that is controlled by an I2C compatible 2 wire serial interface. The XR18910 is designed to accept 8 differential inputs. ■■ ■■ If fewer than 4 differential inputs are required, tie the unused inputs to GND. If single ended inputs are required, tie the unused inputs to 1.5V. The input common mode range of the XR18910 is typically 0.6V to 2.4V when running from a 3.3V supply. The XR18910 offers a very wide gain range. In most cases, the output voltage swing will be the limiting factor. When the XR18910 is powered-up, the default input selected is Channel 1. 2 Inputs are selected via I C using one of 8 register addresses 0x10, 0x12, 0x14, 0x15, 0x18, 0x1A, 0x1C, or 0x1E. Refer to the Register List in Table 1. Example: The example below illustrates how to select Channel 4. Step 1 0 Master sends start condition S Step 2 7 6 5 4 3 2 1 0 Master sends XR18910 address with write bit 1 1 0 0 1 1 1 0 7-bit XR18910 Address = 0x67 W Gain Selection The XR18910 offers 8 selectable fixed gains ranging from 2V/V to 760V/V. When the XR18910 is powered-up, the default gain is 2V/V. The gain is selected via I2C using the register address 0x06 followed by another byte of data to select the gain. Refer to the Register List in Table 1 and the Gain Register list in Table 3. Example: The example below illustrates how to select a gain of 150V/V. To start communication with the XR18910, repeat steps 1-3 as shown in the Inputs and Input Selection section on page 14. Step 4 7 6 5 4 3 2 1 0 Master sends address of register to access 0 0 0 0 0 1 1 0 Gain Select register address = 0x06 Step 5 9 XR18910 sends acknowledge A Since the Gain Select register was accessed, the XR18910 is expecting another byte of data from the master to complete the command. Refer to the “Byte of Parameter” column in the Register List (Table 1). D0 thru D2 are used to select the gain. Refer to the Gain Register list in Table 3, 150V/V is D2 = 1, D1 = 0, and D0 = 0. This translates to a hex code of 0x04, since a full byte of data (8-bits) will be sent. Step 3 9 Step 6 7 6 5 4 3 2 1 0 XR18910 sends acknowledge A Master sends gain register data to select G=150 0 0 0 0 0 1 0 0 Step 4 7 6 5 4 3 2 1 0 Master sends address of register to access 0 0 0 1 0 1 0 1 Gain of 150V/V = 0x04 Select_Input 4 register address = 0x15 Step 5 9 XR18910 sends acknowledge A Step 6 0 Master sends stop condition P Step 7 9 XR18910 sends acknowledge A Step 8 0 Master sends stop condition P NOTES: White Block = host to XR18910, Orange Block = XR18910 to host, Grey Block = Notes. NOTES: White Block = host to XR18910, Orange Block = XR18910 to host, Grey Block = Notes. Rev1C 14/20 XR18910 Application Information (Continued) Offset Correction The XR18910 has a 10-bit offset correction DAC that can be used to provide digital calibration on each of the 8 inputs. Only the offset voltage of the active channel is applied to the PGA. Step 5 9 XR18910 sends acknowledge A The DAC offset of each channel is controlled by the I2C compatible interface. At any time, the master can read or write to any of the DAC offset registers. The DAC offset for each channel is set via I2C using the register addresses 0x20 thru 0x2F followed by another two bytes of data to set the polarity and value of the offset voltage. Refer to the Register List in Table 1. Since a DAC Offset register was accessed, the XR18910 is expecting another two bytes of data from the master to complete the command. Refer to the “Byte of Parameter” column in the Register List (Table 1). D0 thru D9 are used to set the offset voltage and D10 is used to set the sign of the offset voltage, 0 = positive and 1 = negative. Refer to the DAC Offset register list in Table 2. A ±560mV offset correction range is available. The full range of the DAC offset is only available at a gain of 2. At higher gains, the output voltage range of the XR18910 will be exceeded if the full range of the DAC offset is used. The internal 10-bit DAC allows 1,024 different offset voltage settings between 0mV and 560mV. The polarity of the offset correction is set with an additional bit. The unit offset is determined by the following: To determine what DAC output level corresponds to 75mV, use the following equation: Desired Offse t DAC Output Level = Unit Offset A decimal value of 137 corresponds to 75mV. Therefore: ■■ ■■ Total Offset 560mV Unit Offset = DAC Output Levels = 1024 = 547µ V From Table 3: ■■ ■■ ■■ 0x00 (hex) or 0 00 0000 0000 (binary) applies a 0mV offset 0x3FF (hex) or 0 11 1111 1111 (binary) applies a +560mV offset 0x7FF (hex) or 1 11 1111 1111 (binary) applies a -560mV offset 0x89 (hex) or 0 00 1000 1001 (binary) applies a 75mV offset 0x489 (hex) or 1 00 1000 1001 (binary) applies a -75mV offset Step 6 15 14 13 12 11 10 9 8 Master sends 1st byte of DAC offset register data to select an offset of +75mV 0 0 0 0 0 Desired Offset x = Unit Offset See example below for additional information. Example: The example below illustrates how to set the DAC offset for channel 4 to a value of 75mV. To start communication with the XR18910, repeat steps 1-3 as shown in the Inputs and Input Selection section on page 14. 7 6 5 4 3 2 1 0 Master sends address of register to access 0 0 1 0 0 1 0 1 0 0 DAC4 register address = 0x25 2 MSBs of 10-bit DAC output level that corresponds to 137 (0x89) Step 7 9 XR18910 sends acknowledge A Step 8 7 6 5 4 3 2 1 0 1 0 0 0 1 0 0 1 nd Step 4 0 Sign Each DAC output level provides an additional 547µV of offset. To determine what DAC output level corresponds to a specific desired offset, use the following equation: 75mV = 547 µV 137 = Master sends 2 byte of DAC offset register data to select an offset of +75mV 8 LSBs of 10-bit DAC output level that corresponds to 137 (0x89) Step 9 9 XR18910 sends acknowledge A Step 10 0 Master sends stop condition P NOTES: White Block = host to XR18910, Orange Block = XR18910 to host, Grey Block = Notes. Rev1C 15/20 XR18910 Application Information (Continued) LDO Enable / Select (Power to External Bridge Sensors) The XR18910 includes an on-board LDO that provides a regulated voltage that can be used to power external input bridge sensors. Two voltage options are available, 3V and 2.65V. The LDO voltage is selected via the I2C compatible two-wire serial interface. Step 6 7 6 5 4 3 2 1 0 Master sends code to select LDO voltage of 2.65V and Enable LDO during Sleep Mode 0 0 0 0 0 0 0 0 0= Enable 1= 2.65V When the XR18910 is powered-up, the default LDO voltage is 3V. When the XR18910 is active (not in sleep mode), the LDO is always on. If the LDO voltage is not used, the LDO output can be left floating. The LDO can either stay on or shut down while the XR18910 is in Sleep Mode. ■■ ■■ Set LDO to shut down while XR18910 is in Sleep Mode to save power Set LDO to stay on while XR18910 is in Sleep Mode to improve wake-up time The LDO voltage and disable setting are selected via I2C using the register address 0x07 followed by another byte of data to select the voltage and disable setting. Refer to the Register List in Table 1 and the example below for more information. Step 7 9 XR18910 sends acknowledge A Step 8 0 Master sends stop condition P NOTES: White Block = host to XR18910, Orange Block = XR18910 to host, Grey Block = Notes. Example: The example below illustrates how to select an LDO voltage of 2.65V and keep the LDO enabled during Sleep Mode. Current Sense Mode (Monitoring the LDO Current) Current Sense Mode is activated via I2C using the register address 0x08. When activated, the LDO current is sensed and a proportional voltage is present at the output of the XR18910 (ILDO = VOUT/RL). Current Sense Mode stays active until the XR18910 receives any input select command (0x10, 0x12, 0x14, 0x15, 0x18, 0x1A, 0x1C, or 0x1E). To start communication with the XR18910, repeat steps 1-3 as shown in the Inputs and Input Selection section on page 14. Current sense mode can be used to monitor the change over time of the bridge impedance. Step 4 7 6 5 4 3 2 1 0 Master sends address of register to access 0 0 0 0 0 1 1 1 Sleep Mode (Analog Power Down) Sleep mode is activated via I2C using the register address 0x05. When activated, the XR18910 will enter sleep mode. During sleep mode, the analog portion of the XR18910 is disabled. All register settings are retained during sleep mode. LDO Settings register address = 0x07 Step 5 9 XR18910 sends acknowledge A During sleep mode, the nominal supply current will drop below 70µA (with LDO on) and below 45µA (with LDO off). Since the LDO Settings register was accessed, the XR18910 is expecting another byte of data from the master to complete the command. Refer to the “Byte of Parameter” column in the Register List (Table 1). D0 and D1 are used to select the LDO voltage and enable/disable the LDO during Sleep Mode. Bit 0 (D0) controls the LDO voltage (0: 3V; 1: 2.65V). Bit 1 (D1) is only applicable in Sleep Mode. Bit 1 controls whether the LDO shuts down or stays on during sleep mode (0: Enable; 1: Disable). When the XR18910 is active, the LDO is always on. Rev1C During sleep mode, the master can read the value in any register that saves a value during sleep mode. The only I2C commands that can be received or processed are the SLEEP_OUT (wake up) command (0x04) and the LDO on/off and voltage command (0x07). All other register addresses will be ignored. Register address 0x04 is used to return to normal operation (exit Sleep Mode). By default, the XR18910 is active. 16/20 XR18910 Application Information (Continued) Typical Application – 8:1 Bridge Sensor Interface The XR18910 was designed to interface multiple bridge sensors with a microcontroller or FPGA as illustrated in Figure 25. The bridge output signal is differential (VO+ and VO-). Ideally, the unloaded bridge output is zero (VO+ and VO- are identical). However, in-exact resistive values result in a difference between VO+ and VO-. This bridge offset voltage can be substantial and vary between sensors. The XR18910 provides the ability to calibrate the bridge offset on each of the 8 bridge sensors using the on-board DAC. VDD VCC 6.8μF 6.8μF 0.1μF 0.1μF + + BRDG VCC VDD 0.1μF BRIDGE 8 LDO IN8+ IN8- INA / PGA 8:1 MUX BRIDGE 1 10k ADC µC 10nF ±560mV OFFSET TRIM 10-BIT DAC IN1+ IN1- OUT VDD PGA 4.7k VDD 4.7k SDA I2C CONTROL SCL XR18910 AGND DGND Figure 25. 8:1 Bridge Sensor Interface Layout Considerations General layout and supply bypassing play major roles in high frequency performance. Follow the steps below as a basis for high frequency layout: ■■ ■■ ■■ ■■ ■■ Include 6.8µF and 0.1µF ceramic capacitors for power supply decoupling Place the 6.8µF capacitor within 0.75 inches of the power pin Place the 0.1µF capacitor within 0.1 inches of the power pin Connection to the exposed pad is not required. Exposed pad can be connected to ground (GND). Minimize all trace lengths to reduce series inductances Rev1C 17/20 XR18910 Mechanical Dimensions TQFN24 3.5 x 3.5 BOTTOM VIEW TOP VIEW SIDE VIEW TERMINAL DETAILS Drawing No.: POD-00000070 Revision: B Rev1C 18/20 XR18910 Recommended Land Pattern and Stencil TQFN24 3.5 x 3.5 TYPICAL RECOMMENDED LAND PATTERN TYPICAL RECOMMENDED STENCIL Drawing No.: POD-00000070 Revision: B Rev1C 19/20 XR18910 Ordering Information(1) Part Number Operating Temperature Range Lead-Free Package XR18910ILTR-67 Packaging Method Tape and Reel XR18910ILMTR-67 XR18910ILMTR-66 Yes(2) -40°C to 85°C 3.5mm x 3.5mm TQFN-24 XR18910ILMTR-65 Tape and Mini Reel XR18910ILMTR-64 XR18910ILEVB Evaluation board NOTES: 1. Refer to www.exar.com/XR18910 for most up-to-date Ordering Information. 2. Visit www.exar.com for additional information on Environmental Rating. Revision History Revision Date Description 1A March 2016 Initial Release 1B May 2016 1C March 2018 Added clarity to I2C Bus Addressing section. Updated Table 4. Updated Step 2 in Inputs and Input Selection section. Updated to MaxLinear logo. Updated format and Ordering Information. Added I2C Power Up section. Package name updated to TQFN. Corporate Headquarters: 5966 La Place Court Suite 100 Carlsbad, CA 92008 Tel.:+1 (760) 692-0711 Fax: +1 (760) 444-8598 www.maxlinear.com High Performance Analog: 1060 Rincon Circle San Jose, CA 95131 Tel.: +1 (669) 265-6100 Fax: +1 (669) 265-6101 Email: hpatechsupport@exar.com www.exar.com The content of this document is furnished for informational use only, is subject to change without notice, and should not be construed as a commitment by MaxLinear, Inc.. MaxLinear, Inc. assumes no responsibility or liability for any errors or inaccuracies that may appear in the informational content contained in this guide. Complying with all applicable copyright laws is the responsibility of the user. Without limiting the rights under copyright, no part of this document may be reproduced into, stored in, or introduced into a retrieval system, or transmitted in any form or by any means (electronic, mechanical, photocopying, recording, or otherwise), or for any purpose, without the express written permission of MaxLinear, Inc. Maxlinear, Inc. does not recommend the use of any of its products in life support applications where the failure or malfunction of the product can reasonably be expected to cause failure of the life support system or to significantly affect its safety or effectiveness. Products are not authorized for use in such applications unless MaxLinear, Inc. receives, in writing, assurances to its satisfaction that: (a) the risk of injury or damage has been minimized; (b) the user assumes all such risks; (c) potential liability of MaxLinear, Inc. is adequately protected under the circumstances. MaxLinear, Inc. may have patents, patent applications, trademarks, copyrights, or other intellectual property rights covering subject matter in this document. Except as expressly provided in any written license agreement from MaxLinear, Inc., the furnishing of this document does not give you any license to these patents, trademarks, copyrights, or other intellectual property. Company and product names may be registered trademarks or trademarks of the respective owners with which they are associated. © 2016 - 2018 MaxLinear, Inc. All rights reserved XR18910_DS_042018 Rev1C 20/20