XRA1201IL24-F

XRA1201 / XRA1201P 16-bit I2C / SMBUS GPIO EXPANDER February 2, 2022 Rev. 1.0.2 GENERAL DESCRIPTION FEATURES The XRA1201/1201P is a 16-bit GPIO expander with After power-up, the an I2C/SMBus interface. XRA1201 has internal 100K ohm pull-up resistors on each I/O pin that can be individually enabled. The XRA1201P has the internal pull-up resistors enabled upon power-up in case it is necessary for the inputs to be in a known state.  In addition, the GPIOs on the XRA1201/1201P can individually be controlled and configured. As outputs, the GPIOs can be outputs that are high, low or in three-state mode. The three-state mode feature is useful for applications where the power is removed from the remote devices, but they may still be connected to the GPIO expander. As inputs, the internal pull-up resistors can be enabled or disabled and the input polarity can be inverted. The interrupt can be programmed for different behaviors. The interrupts can be programmed to generate an interrupt on the rising edge, falling edge or on both edges. The interrupt can be cleared if the input changes back to its original state or by reading the current state of the inputs. The XRA1201/1201P are enhanced versions of other 16-bit GPIO expanders with an I2C/SMBus interface. The XRA1201 is pin and software compatible with the PCA9535, TCA9535 and MAX7312. The XRA1201P is pin and software compatible with the CAT9555, PCA9555, TCA9555, MAX7311 and MAX7318. The XRA1201/1201P are available in 24-pin QFN and 24-pin TSSOP packages. 1.65V to 3.6V operating voltage 16 General Purpose I/Os (GPIOs)  5V tolerant inputs  Maximum stand-by current of 1uA at +1.8V  I2C/SMBus bus interface  I2C clock frequency up to 400kHz  Noise filter on SDA and SCL inputs  Up to 32 I2C Slave Addresses Individually programmable inputs Internal pull-up resistors Polarity inversion Individual interrupt enable Rising edge and/or Falling edge interrupt Input filter Individually programmable outputs Output Level Control Output Three-State Control Open-drain active low interrupt output Pin and software compatible with PCA9535, TCA9535, MAX7312 (XRA1201) Pin and software compatible with CAT9555, PCA9555, TCA9555, MAX7311 and MAX7318 (XRA1201P) 3kV HBM ESD protection per JESD22-A114F 200mA latch-up performance per JESD78B                APPLICATIONS Personal Digital Assistants (PDA) Cellular Phones/Data Devices  Battery-Operated Devices  Global Positioning System (GPS)  Bluetooth   1 XRA1201 / XRA1201P 16-bit I2C / SMBUS GPIO Expander FIGURE 1. XRA1201 BLOCK DIAGRAM VCC (1 .6 5 V – 3 .6 V ) G P IO s P0 P1 P2 P3 P4 P5 P6 P7 G P IO s P8 P9 P10 P11 P12 P13 P14 P15 SCL SDA I2 C / SM Bus In te rfa c e A2 A1 A0 G P IO C o n tro l R e g is te rs IR Q # GND ORDERING INFORMATION PART NUMBER NUMBER OF GPIOS OPERATING TEMPERATURE RANGE PACKAGE PACKAGE METHOD LEAD-FREE XRA1201IL24TR-F 16 -40°C to +85°C QFN-24 Tape and Reel Yes XRA1201PIL24-F 16 -40°C to +85°C QFN-24 Tray Yes XRA1201IG24TR-F 16 -40°C to +85°C TSSOP-24 Tape and Reel Yes XRA1201PIG24TR-F 16 -40°C to +85°C TSSOP-24 Tape and Reel Yes XRA1201IL24-0A-EB XRA1201IL24TR-F Evaluation Board XRA1201IG24-0A-EB XRA1201IG24TR-F Evaluation Board XRA1201PIL24-0A-EB XRA1201PIL24-F Evaluation Board XRA1201PIG24-0A-EB XRA1201PIG24TR-F Evaluation Board NOTE: For more information about part numbers, as well as the most up-to-date ordering information and additional information on environmental rating, go to www.maxlinear.com/XRA1201 and www.maxlinear.com/XRA1201P. SCL SDA IRQ# VCC A1 A2 FIGURE 2. PIN OUT ASSIGNMENTS 24 23 22 21 20 19 P0 1 P1 2 18 A0 17 P15 XRA1201/ XRA1201P 24-Pin QFN P2 3 P3 4 P4 5 229DSR00 24 VCC A1 2 23 SDA A2 3 22 SCL P0 4 21 A0 P1 5 20 P15 16 P14 P2 6 15 P13 14 P12 P3 7 13 P11 XRA1201/ XRA1201P 24-Pin TSSOP 19 P14 18 P13 16 P11 P6 10 15 P10 P7 11 14 P9 GND 12 13 P8 P9 P5 9 P10 9 10 11 12 P8 8 GND 17 P12 7 P7 P4 8 P6 P5 6 IRQ# 1 2 Rev. 1.0.2 XRA1201 / XRA1201P 16-bit I2C / SMBUS GPIO Expander PIN DESCRIPTIONS Pin Description NAME QFN-24 TSSOP-24 TYPE PIN# PIN# DESCRIPTION I2C INTERFACE SDA 20 23 I/O SCL 19 22 I IRQ# 22 1 OD A0 A1 A2 18 23 24 21 2 3 I I I P0 P1 P2 P3 P4 P5 P6 P7 1 2 3 4 5 6 7 8 4 5 6 7 8 9 10 11 I/O I/O I/O I/O I/O I/O I/O I/O General purpose I/Os P0-P7. All GPIOs are configured as inputs upon power-up. After power-up, the internal pull-up resistors are enabled for the XRA1201P. The internal pull-up resistors are disabled for the XRA1201. P8 P9 P10 P11 P12 P13 P14 P15 10 11 12 13 14 15 16 17 13 14 15 16 17 18 19 20 I/O I/O I/O I/O I/O I/O I/O I/O General purpose I/O P8-P15. All GPIOs are configured as inputs upon power-up. After power-up, the internal pull-up resistors are enabled for the XRA1201P. The internal pull-up resistors are disabled for the XRA1201. I2C-bus data input/output (open-drain). I2C-bus serial input clock. Interrupt output (open-drain, active LOW). These pins select the I2C slave address. See Table 1. GPIOs ANCILLARY SIGNALS VCC 21 24 Pwr 1.65V to 3.6V VCC supply voltage. GND 9 12 Pwr Power supply common, ground. GND Center Pad - Pwr The exposed pad at the bottom surface of the package is designed for thermal performance. Use of a center pad on the PCB is strongly recommended for thermal conductivity as well as to provide mechanical stability of the package on the PCB. The center pad is recommended to be solder masked defined with opening size less than or equal to the exposed thermal pad on the package bottom to prevent solder bridging to the outer leads of the device. Thermal vias must be connected to GND plane as the thermal pad of package is at GND potential. Pin type: I=Input, O=Output, I/O= Input/output, OD=Output Open Drain. 229DSR00 3 Rev. 1.0.2 XRA1201 / XRA1201P 16-bit 1.0 I2C / SMBUS GPIO Expander FUNCTIONAL DESCRIPTIONS I2C-bus Interface 1.1 The I2C-bus interface is compliant with the Standard-mode and Fast-mode I2C-bus specifications. The I2C-bus interface consists of two lines: serial data (SDA) and serial clock (SCL). In the Standard-mode, the serial clock and serial data can go up to 100 kbps and in the Fast-mode, the serial clock and serial data can go up to 400 kbps. The first byte sent by an I2C-bus master contains a start bit (SDA transition from HIGH to LOW when SCL is HIGH), 7-bit slave address and whether it is a read or write transaction. The next byte is the sub-address that contains the address of the register to access. The XRA120x responds to each write with an acknowledge (SDA driven LOW by XRA1201/1201P for one clock cycle when SCL is HIGH). The last byte sent by an I2Cbus master contains a stop bit (SDA transition from LOW to HIGH when SCL is HIGH). See Figures 3 - 5 below. For complete details, see the I2C-bus specifications. FIGURE 3. I2C START AND STOP CONDITIONS SDA SCL S P START condition STOP condition FIGURE 4. MASTER WRITES TO SLAVE S SLAVE ADDRESS W A COMM AND BYTE A DATA BYTE A P W h ite b lo c k : h o s t to X R A 1 2 0 x G re y b lo c k : X R A 1 2 0 x to h o s t FIGURE 5. MASTER READS FROM SLAVE S SLAVE ADDRESS W A COMMAND BYTE A S SLAVE ADDRESS R A nDATA A LAST DATA NA White block: host to XRA120x Grey block: XRA120x to host 229DSR00 4 Rev. 1.0.2 P XRA1201 / XRA1201P 16-bit 1.1.1 I2C / SMBUS GPIO Expander I2C-bus Addressing There could be many devices on the I2C-bus. To distinguish itself from the other devices on the I2C-bus, the XRA1201/1201P has up to 32 I2C slave addresses using the A2-A0 address lines. Table 1 below shows the different addresses that can be selected. TABLE 1: I2C ADDRESS MAP 229DSR00 A2 A1 A0 I2C ADDRESS GND SCL GND 0x20 (0010 000X) GND SCL VCC 0x22 (0010 001X) GND SDA GND 0x24 (0010 010X) GND SDA VCC 0x26 (0010 011X) VCC SCL GND 0x28 (0010 100X) VCC SCL VCC 0x2A (0010 101X) VCC SDA GND 0x2C (0010 110X) VCC SDA VCC 0x2E (0010 111X) GND SCL SCL 0x30 (0011 000X) GND SCL SDA 0x32 (0011 001X) GND SDA SCL 0x34 (0011 010X) GND SDA SDA 0x36 (0011 011X) VCC SCL SCL 0x38 (0011 100X) VCC SCL SDA 0x3A (0011 101X) VCC SDA SCL 0x3C (0011 110X) VCC SDA SDA 0x3E (0011 111X) GND GND GND 0x40 (0100 000X) GND GND VCC 0x42 (0100 001X) GND VCC GND 0x44 (0100 010X) GND VCC VCC 0x46 (0100 011X) VCC GND GND 0x48 (0100 100X) VCC GND VCC 0x4A (0100 101X) VCC VCC GND 0x4C (0100 110X) VCC VCC VCC 0x4E (0100 111X) GND GND SCL 0x50 (0101 000X) GND GND SDA 0x52 (0101 001X) GND VCC SCL 0x54 (0101 010X) GND VCC SDA 0x56 (0101 011X) VCC GND SCL 0x58 (0101 100X) VCC GND SDA 0x5A (0101 101X) VCC VCC SCL 0x5C (0101 110X) VCC VCC SDA 0x5E (0101 111X) 5 Rev. 1.0.2 XRA1201 / XRA1201P 16-bit I2C / SMBUS GPIO Expander I2C Read and Write 1.1.2 A read or write transaction is determined by bit-0 of the slave address. If bit-0 is ’0’, then it is a write transaction. If bit-0 is ’1’, then it is a read transaction. I2C Command Byte 1.1.3 An I2C command byte is sent by the I2C master following the slave address. The command byte indicates the address offset of the register that will be accessed. Table 2 below lists the command bytes for each register. TABLE 2: I2C COMMAND BYTE (REGISTER ADDRESS) COMMAND BYTE 229DSR00 REGISTER NAME DESCRIPTION READ/WRITE DEFAULT VALUES 0x00 GSR1 - GPIO State for P0-P7 Read-Only 0xXX 0x01 GSR2 - GPIO State for P8-P15 Read-Only 0xXX 0x02 OCR1 - Output Control for P0-P7 Read/Write 0xFF 0x03 OCR2 - Output Control for P8-P15 Read/Write 0xFF 0x04 PIR1 - Input Polarity Inversion for P0-P7 Read/Write 0x00 0x05 PIR2 - Input Polarity Inversion for P8-P15 Read/Write 0x00 0x06 GCR1 - GPIO Configuration for P0-P7 Read/Write 0xFF 0x07 GCR2 - GPIO Configuration for P8-P15 Read/Write 0xFF 0x08 PUR1 - Input Internal Pull-up Resistor Enable/Disable for P0-P7 Read/Write 0x00 (XRA1201) 0xFF (XRA1201P) 0x09 PUR2 - Input Internal Pull-up Resistor Enable/Disable for P8-P15 Read/Write 0x00 (XRA1201) 0xFF (XRA1201P) 0x0A IER1 - Input Interrupt Enable for P0-P7 Read/Write 0x00 0x0B IER2 - Input Interrupt Enable for P8-P15 Read/Write 0x00 0x0C TSCR1 - Output Three-State Control for P0-P7 Read/Write 0x00 0x0D TSCR2 - Output Three-State Control for P8-P15 Read/Write 0x00 0x0E ISR1 - Input Interrupt Status for P0-P7 Read 0x00 0x0F ISR2 - Input Interrupt Status for P8-P15 Read 0x00 0x10 REIR1 - Input Rising Edge Interrupt Enable for P0-P7 Read/Write 0x00 0x11 REIR2 - Input Rising Edge Interrupt Enable for P8-P15 Read/Write 0x00 0x12 FEIR1 - Input Falling Edge Interrupt Enable for P0-P7 Read/Write 0x00 0x13 FEIR2 - Input Falling Edge Interrupt Enable for P8-P15 Read/Write 0x00 0x14 IFR1 - Input Filter Enable/Disable for P0-P7 Read/Write 0xFF 0x15 IFR2 - Input Filter Enable/Disable for P8-P15 Read/Write 0xFF 6 Rev. 1.0.2 XRA1201 / XRA1201P 16-bit 1.2 I2C / SMBUS GPIO Expander Interrupts The table below summarizes the interrupt behavior of the different register settings for the XRA1201/1201P. TABLE 3: INTERRUPT GENERATION AND CLEARING GCR IER REIR FEIR IFR BIT BIT BIT BIT BIT 1 1 0 1 X 0 X 0 1 1 1 0 1 1 0 1 INTERRUPT GENERATED BY: X No interrupts enabled (default) N/A 0 A rising or falling edge on the input 1 A rising or falling edge on the input and remains in the new state for more than 1075ns Reading the GSR register or if the input changes back to its previous state (state of input during last read to GSR) 0 A rising edge on the input 1 A rising edge on the input and remains high for more than 1075ns 0 A falling edge on the input 1 A falling edge on the input and remains low for more than 1075ns 0 A rising or falling edge on the input Reading the GSR register Reading the GSR register 1 1 1 1 1 A rising or falling edge on the input and remains in the new state for more than 1075ns 0 x x x x No interrupts in output mode 229DSR00 INTERRUPT CLEARED BY: Reading the GSR register N/A 7 Rev. 1.0.2 XRA1201 / XRA1201P 16-bit 2.0 2.1 I2C / SMBUS GPIO Expander REGISTER DESCRIPTION GPIO State Register 1 (GSR1) - Read-Only The status of P7 - P0 can be read via this register. A read will show the current state of these pins (or the inverted state of these pins if enabled via the PIR Register). Reading this register will clear an input interrupt (see Table 3 for complete details). Reading this register will also return the last value written to the OCR register for any pins that are configured as outputs (ie. this is not the same as the state of the actual output pin since the output pin can be in three-state mode). A write to this register has no effect. The MSB of this register corresponds with P7 and the LSB of this register corresponds with P0. 2.2 GPIO State Register 2 (GSR2) - Read-Only The status of P15 - P8 can be read via this register. A read will show the current state of these pins (or the inverted state of these pins if enabled via the PIR Register). Reading this register will clear an input interrupt (see Table 3 for complete details). Reading this register will also return the last value written to the OCR register for any pins that are configured as outputs (ie. this is not the same as the state of the actual output pin since the output pin can be in three-state mode). A write to this register has no effect. The MSB of this register corresponds with P15 and the LSB of this register corresponds with P8. 2.3 Output Control Register 1 (OCR1) - Read/Write When P7 - P0 are defined as outputs, they can be controlled by writing to this register. Reading this register will return the last value written to it, however, this value may not be the actual state of the output pin since these pins can be in three-state mode. The MSB of this register corresponds with P7 and the LSB of this register corresponds with P0. 2.4 Output Control Register 2 (OCR2) - Read/Write When P15 - P8 are defined as outputs, they can be controlled by writing to this register. Reading this register will return the last value written to it, however, this value may not be the actual state of the output pin since these pins can be in three-state mode. The MSB of this register corresponds with P15 and the LSB of this register corresponds with P8. 2.5 Input Polarity Inversion Register 1 (PIR1) - Read/Write When P7 - P0 are defined as inputs, this register inverts the polarity of the input value read from the Input Port Register. If the corresponding bit in this register is set to ’1’, the value of this bit in the GSR Register will be the inverted value of the input pin. If the corresponding bit in this register is set to ’0’, the value of this bit in the GSR Register will be the actual value of the input pin. The MSB of this register corresponds with P7 and the LSB of this register corresponds with P0. 2.6 Input Polarity Inversion Register 2 (PIR2) - Read/Write When P15 - P8 are defined as inputs, this register inverts the polarity of the input value read from the Input Port Register. If the corresponding bit in this register is set to ’1’, the value of this bit in the GSR Register will be the inverted value of the input pin. If the corresponding bit in this register is set to ’0’, the value of this bit in the GSR Register will be the actual value of the input pin. The MSB of this register corresponds with P15 and the LSB of this register corresponds with P8. 2.7 GPIO Configuration Register 1 (GCR1) - Read/Write This register configures the GPIOs as inputs or outputs. After power-up, the GPIOs are inputs. Setting these bits to ’0’ will enable the GPIOs as outputs. Setting these bits to ’1’ will enable the GPIOs as inputs. The MSB of this register corresponds with P7 and the LSB of this register corresponds with P0. 2.8 GPIO Configuration Register 2 (GCR2) - Read/Write This register configures the GPIOs as inputs or outputs. After power-up, the GPIOs are inputs. Setting these bits to ’0’ will enable the GPIOs as outputs. Setting these bits to ’1’ will enable the GPIOs as inputs. The MSB of this register corresponds with P15 and the LSB of this register corresponds with P8. 229DSR00 8 Rev. 1.0.2 XRA1201 / XRA1201P 16-bit 2.9 I2C / SMBUS GPIO Expander Input Internal Pull-up Enable/Disable Register 1 (PUR1) - Read/Write This register enables/disables the internal pull-up resistors for an input. After power-up, the internal pull-up resistors are disabled for the XRA1201. Writing a ’1’ to these bits will enable the internal pull-up resistors. After power-up, the internal pull-up resistors are enabled for the XRA1201P. Writing a ’0’ to these bits will disable the internal pull-up resistors. The MSB of this register corresponds with P7 and the LSB of this register corresponds with P0. 2.10 Input Internal Pull-up Enable/Disable Register 2 (PUR2) - Read/Write This register enables/disables the internal pull-up resistors for an input. After power-up, the internal pull-up resistors are disabled for the XRA1201. Writing a ’1’ to these bits will enable the internal pull-up resistors. After power-up, the internal pull-up resistors are enabled for the XRA1201P. Writing a ’0’ to these bits will disable the internal pull-up resistors. The MSB of this register corresponds with P15 and the LSB of this register corresponds with P8. 2.11 Input Interrupt Enable Register 1 (IER1) - Read/Write This register enables/disables the interrupts for an input. After power-up, the interrupts are disabled. Writing a ’1’ to these bits will enable the interrupt for the corresponding input pins. See Table 3 for complete details of the interrupt behavior for various register settings. No interrupts are generated for outputs when GCR bit is 0. The MSB of this register corresponds with P7 and the LSB of this register corresponds with P0. 2.12 Input Interrupt Enable Register 2 (IER2) - Read/Write This register enables/disables the interrupts for an input. After power-up, the interrupts are disabled. Writing a ’1’ to these bits will enable the interrupt for the corresponding input pins. See Table 3 for complete details of the interrupt behavior for various register settings. No interrupts are generated for outputs when GCR bit is 0. The MSB of this register corresponds with P15 and the LSB of this register corresponds with P8. 2.13 Output Three-State Control Register 1 (TSCR1) - Read/Write This register can enable/disable the three-state mode of an output. Writing a ’1’ to these bits will enable the three-state mode for the corresponding output pins. The MSB of this register corresponds with P7 and the LSB of this register corresponds with P0. 2.14 Output Three-State Control Register 2 (TSCR2) - Read/Write This register can enable/disable the three-state mode of an output. Writing a ’1’ to these bits will enable the three-state mode for the corresponding output pins. The MSB of this register corresponds with P15 and the LSB of this register corresponds with P8. 2.15 Input Interrupt Status Register 1 (ISR1) - Read-Only This register reports the input pins that have generated an interrupt. See Table 3 for complete details of the interrupt behavior for various register settings. The MSB of this register corresponds with P7 and the LSB of this register corresponds with P0. 2.16 Input Interrupt Status Register 2 (ISR2) - Read-Only This register reports the input pins that have generated an interrupt. See Table 3 for complete details of the interrupt behavior for various register settings. The MSB of this register corresponds with P15 and the LSB of this register corresponds with P8. 229DSR00 9 Rev. 1.0.2 XRA1201 / XRA1201P 16-bit 2.17 I2C / SMBUS GPIO Expander Input Rising Edge Interrupt Enable Register 1 (REIR1) - Read/Write Writing a ’1’ to these bits will enable the corresponding input to generate an interrupt on the rising edge. See Table 3 for complete details of the interrupt behavior for various register settings. The MSB of this register corresponds with P7 and the LSB of this register corresponds with P0. 2.18 Input Rising Edge Interrupt Enable Register 2 (REIR2) - Read/Write Writing a ’1’ to these bits will enable the corresponding input to generate an interrupt on the rising edge. See Table 3 for complete details of the interrupt behavior for various register settings. The MSB of this register corresponds with P15 and the LSB of this register corresponds with P8. 2.19 Input Falling Edge Interrupt Enable Register 1 (FEIR1) - Read/Write Writing a ’1’ to these bits will enable the corresponding input to generate an interrupt on the falling edge. Writing a ’1’ to these bits will make that input generate an interrupt on the rising edge only. See Table 3 for complete details of the interrupt behavior for various register settings. The MSB of this register corresponds with P7 and the LSB of this register corresponds with P0. 2.20 Input Falling Edge Interrupt Enable Register 2 (FEIR2) - Read/Write Writing a ’1’ to these bits will enable the corresponding input to generate an interrupt on the falling edge. Writing a ’1’ to these bits will make that input generate an interrupt on the rising edge only. See Table 3 for complete details of the interrupt behavior for various register settings. The MSB of this register corresponds with P15 and the LSB of this register corresponds with P8. 2.21 Input Filter Enable Register 1 (IFR1) - Read/Write By default, the input filters are enabled (IFR = 0xFF). When the input filters are enabled, any pulse that is greater than 1075ns will generate an interrupt (if enabled). Pulses that are less than 225ns will be filtered and will not generate an interrupt. Pulses in between this range may or may not generate an interrupt. Writing a ’0’ to these bits will disable the input filter for the corresponding inputs. With the input filters disabled, any change on the inputs will generate an interrupt (if enabled). See Table 3 for complete details of the interrupt behavior for various register settings. The MSB of this register corresponds with P7 and the LSB of this register corresponds with P0. 2.22 Input Filter Enable Register 2 (IFR2) - Read/Write By default, the input filters are enabled (IFR = 0xFF). When the input filters are enabled, any pulse that is greater than 1075ns will generate an interrupt (if enabled). Pulses that are less than 225ns will be filtered and will not generate an interrupt. Pulses in between this range may or may not generate an interrupt. Writing a ’0’ to these bits will disable the input filter for the corresponding inputs. With the input filters disabled, any change on the inputs will generate an interrupt (if enabled). See Table 3 for complete details of the interrupt behavior for various register settings. The MSB of this register corresponds with P15 and the LSB of this register corresponds with P8. 229DSR00 10 Rev. 1.0.2 XRA1201 / XRA1201P 16-bit I2C / SMBUS GPIO Expander ABSOLUTE MAXIMUM RATINGS Power supply voltage 3.6 Volts Supply current 160 mA Ground current 200 mA External current limit of each GPIO 25 mA Total current limit for GPIO[15:8] and GPIO[7:0] 100 mA Total current limit for GPIO[15:0] 200 mA Total supply current sourced by all GPIOs 160 mA Operating Temperature -40o to +85oC Storage Temperature -65o to +150oC Power Dissipation 200 mW TYPICAL PACKAGE THERMAL RESISTANCE DATA (MARGIN OF ERROR: ± 15%) Thermal Resistance (24-QFN) theta-ja = 38oC/W, theta-jc = 26oC/W Thermal Resistance (24-TSSOP) theta-ja = 84oC/W, theta-jc = 16oC/W 229DSR00 11 Rev. 1.0.2 XRA1201 / XRA1201P 16-bit I2C / SMBUS GPIO Expander ELECTRICAL CHARACTERISTICS DC ELECTRICAL CHARACTERISTICS UNLESS OTHERWISE NOTED: TA = -40O TO +85OC, VCC IS 1.65V TO 3.6V LIMITS SYMBOL LIMITS 1.8V 10% PARAMETER 2.5V 10% LIMITS 3.3V 10% MIN MAX MIN MAX MIN MAX UNITS CONDITIONS VIL Input Low Voltage -0.3 0.3VCC -0.3 0.3VCC -0.3 0.3VCC V Note 1 VIL Input Low Voltage -0.3 0.2 -0.3 0.5 -0.3 0.8 V Note 2 VIH Input High Voltage 1.3 VCC 1.8 VCC 2.3 VCC V Note 1 VIH Input High Voltage 1.4 5.5 1.8 5.5 2.0 5.5 V Note 2 VOL Output Low Voltage 0.4 V V V IOL = 3 mA 0.4 0.4 IOL = 3 mA IOL = 3 mA Note 3 VOL Output Low Voltage 0.5 0.5 0.5 V IOL = 8 mA Note 4 VOL Output Low Voltage 0.4 0.4 0.4 V V V IOL = 6 mA IOL = 4 mA IOL = 1.5 mA Note 5 VOH Output High Voltage 2.6 V V V 1.8 1.2 IOH = -8 mA IOH = -8 mA IOH = -8 mA Note 4 IIL Input Low Leakage Current ±10 ±10 ±10 uA IIH Input High Leakage Current ±10 ±10 ±10 uA CIN Input Pin Capacitance 5 5 5 pF ICC Power Supply Current 50 100 200 uA Test 1 ICC Power Supply Current 150 250 500 uA Test 2 ICCS Standby Current 1 2 5 uA Test 3 140 k 100k 40% RGPIO GPIO pull-up resistance 60 140 60 140 60 NOTES: 1. For I2C input signals (SDA, SCL); 2. For GPIOs, A0, A1 and A2 signals; 3. For I2C output signal SDA; 4. For GPIOs; 5. For IRQ# signal; 229DSR00 12 Rev. 1.0.2 XRA1201 / XRA1201P 16-bit I2C / SMBUS GPIO Expander Test 1: SCL frequency is 400 KHz with internal pull-ups disabled. All GPIOs are configured as inputs. All inputs are steady at VCC or GND. Outputs are floating or in the tri-state mode. Test 2: SCL frequency is 400 KHz with internal pull-ups enabled. All GPIOs are configured as inputs. All inputs are steady at VCC or GND. Outputs are floating or in the tri-state mode. Test 3: All inputs are steady at VCC or GND to minimize standby current. If internal pull-up is enabled, input voltage level should be the same as VCC. All GPIOs are configured as inputs. SCL and SDA are at VCC. Outputs are left floating or in tri-state mode. AC ELECTRICAL CHARACTERISTICS Unless otherwise noted: TA=-40o to +85oC, Vcc=1.65V - 3.6V STANDARD MODE SYMBOL 2 PARAMETER I C-BUS MIN MAX 100 I2C-BUS MIN MAX Operating frequency TBUF Bus free time between STOP and START 4.7 1.3 s THD;STA START condition hold time 4.0 0.6 s TSU;STA START condition setup time 4.7 0.6 s THD;DAT Data hold time 0 0 ns TVD;ACK Data valid acknowledge 0.6 0.6 s TVD;DAT SCL LOW to data out valid 0.6 0.6 ns TSU;DAT Data setup time 250 150 ns TLOW Clock LOW period 4.7 1.3 s THIGH Clock HIGH period 4.0 0.6 s TF Clock/data fall time 300 300 ns TR Clock/data rise time 1000 300 ns TSP Pulse width of spikes tolerance TD1 I2C-bus GPIO output valid 0.2 0.2 s TD4 I2C input pin interrupt valid 4 4 s TD5 I2C input pin interrupt clear 4 4 s TD15 SCL delay after reset 50 3 13 0 400 UNIT fSCL 229DSR00 0 FAST MODE 50 3 kHz ns s Rev. 1.0.2 XRA1201 / XRA1201P 16-bit I2C / SMBUS GPIO Expander FIGURE 6. I2C-BUS TIMING DIAGRAM START condition (S) Protocol Bit 7 MSB (A7) T SU;STA 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 7. WRITE TO OUTPUT SDA SLAVE ADDRESS W A COMMAND BYTE A DATA A T D1 GPIOn FIGURE 8. GPIO PIN INTERRUPT A C K from sla ve SDA S LA V E ADDRESS W A COM MAND BYTE A A C K from slave S S LA V E ADDRESS R A A C K fro m m aster DATA A P IN T# TD4 TD5 Px 229DSR00 14 Rev. 1.0.2 XRA1201 / XRA1201P 16-bit I2C / SMBUS GPIO Expander MECHANICAL DIMENSIONS (24 PIN QFN - 4 X 4 X 0.9 mm) TOP VIEW BOTTOM VIEW SIDE VIEW TERMINAL DETAILS Drawing No.: POD-00000 142 Revision: A Note: The control dimension is in millimeter. 229DSR00 15 Rev. 1.0.2 XRA1201 / XRA1201P 16-bit I2C / SMBUS GPIO Expander RECOMMENDED LAND PATTERN AND STENCIL (24 PIN QFN - 4 X 4 X 0.9 mm) TYPICAL RECOMMENDED LAND PATTERN TYPICAL RECOMMENDED STENCIL Drawing No.: POD-00000 142 Revision: A Note: The control dimension is in millimeter. 229DSR00 16 Rev. 1.0.2 XRA1201 / XRA1201P 16-bit I2C / SMBUS GPIO Expander MECHANICAL DIMENSIONS (24 PIN TSSOP - 4.4 mm) TOP VIEW BOTTOM VIEW SIDE VIEW - 1 © © SIDE VIEW - 2 TERMINAL DETAILS Drawing No.: POD-00000058 Revision: D Note: The control dimension is in millimeter. 229DSR00 17 Rev. 1.0.2 XRA1201 / XRA1201P 16-bit I2C / SMBUS GPIO Expander RECOMMENDED LAND PATTERN AND STENCIL (24 PIN TSSOP - 4 X 4 mm) TYPICAL RECOMMENDED LAND PATTERN TYPICAL RECOMMENDED STENCIL Drawing No.: POD-00000058 Revision: D Note: The control dimension is in millimeter. 229DSR00 18 Rev. 1.0.2 2 XRA1201 / XRA1201P 16-bit I C / SMBUS GPIO Expander REVISION HISTORY DATE REVISION DESCRIPTION September 2011 1.0.0 Final Datasheet. August 2020 1.0.1 Update to MaxLinear logo. Update Ordering Information. February 2, 2022 1.0.2 Updated:  In the "TSSOP-16 versions available, QFN-16 versions obsolete" table, GPIOs parameter description.  "GPIO Configuration Register 1 (GCR1) - Read/Write" section.  "GPIO Configuration Register 2 (GCR2) - Read/Write" section.  "Input Internal Pull-up Enable/Disable Register 1 (PUR1) - Read/Write" section.  "Input Interrupt Enable Register 1 (IER1) - Read/Write" section.  "Input Interrupt Enable Register 2 (IER2) - Read/Write" section.  "Input Interrupt Enable Register (IER) - Read/Write" section.  "Mechanical Dimensions (24 pin QFN)" figure.  "Recommended and Pattern and Stencil (24 pin QFN)" figure.  "Mechanical Dimensions (24 pin TSSOP)" figure.  "Recommended Land Pattern and Stencil (24 pin QFN)" figure. 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MaxLinear, the MaxLinear logo, any MaxLinear trademarks (MxL, Full-Spectrum Capture, FSC, G.now, AirPHY, Puma, and AnyWAN), and the MaxLinear logo on the products sold are all property of MaxLinear, Inc. or one of MaxLinear’s subsidiaries in the U.S.A. and other countries. All rights reserved. Other company trademarks and product names appearing herein are the property of their respective owners. ©2022 MaxLinear, Inc. All rights reserved. 229DSR00 19 Rev. 1.0.2