====== Retimer ====== ===== Производители ===== ---- datatable ---- cols : %pageid%, name, country, descr_wiki, link_url, status, tags_tags headers : Page, Manufacturer, Country, Description, link, status, Tags filter : %class%=manufacturers filter : tags_tags~~retimer sort : name ---- ===== Микросхемы ===== ==== TI DS280DF810 ===== {{tablelayout?rowsHeaderSource=Auto&colwidth="53px,137px,73px,155px,,119px,243px,768px"}} ^ NN ^ PIN\\ NAME ^ PIN\\ NO. ^ TYPE ^ Voltage ^ INTERNAL\\ PULL-UP/\\ PULL-DOWN ^ GROUP ^ DESCRIPTION ^ | 1 | RX0P | C15 | Input | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting differential inputs to the equalizer. An on-chip 100-Ω termination resistor connects RXP to RXN. These inputs are AC coupled on-chip with physical 220 nF capacitors. | | 2 | RX0N | B15 | Input | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting differential inputs to the equalizer. An on-chip 100-Ω termination resistor connects RXP to RXN. These inputs are AC coupled on-chip with physical 220 nF capacitors. | | 3 | RX1P | B13 | Input | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting differential inputs to the equalizer. An on-chip 100-Ω termination resistor connects RXP to RXN. These inputs are AC coupled on-chip with physical 220 nF capacitors. | | 4 | RX1N | A13 | Input | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting differential inputs to the equalizer. An on-chip 100-Ω termination resistor connects RXP to RXN. These inputs are AC coupled on-chip with physical 220 nF capacitors. | | 5 | RX2P | B11 | Input | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting differential inputs to the equalizer. An on-chip 100-Ω termination resistor connects RXP to RXN. These inputs are AC coupled on-chip with physical 220 nF capacitors. | | 6 | RX2N | A11 | Input | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting differential inputs to the equalizer. An on-chip 100-Ω termination resistor connects RXP to RXN. These inputs are AC coupled on-chip with physical 220 nF capacitors. | | 7 | RX3P | B9 | Input | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting differential inputs to the equalizer. An on-chip 100-Ω termination resistor connects RXP to RXN. These inputs are AC coupled on-chip with physical 220 nF capacitors. | | 8 | RX3N | A9 | Input | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting differential inputs to the equalizer. An on-chip 100-Ω termination resistor connects RXP to RXN. These inputs are AC coupled on-chip with physical 220 nF capacitors. | | 9 | RX4P | B7 | Input | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting differential inputs to the equalizer. An on-chip 100-Ω termination resistor connects RXP to RXN. These inputs are AC coupled on-chip with physical 220 nF capacitors. | | 10 | RX4N | A7 | Input | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting differential inputs to the equalizer. An on-chip 100-Ω termination resistor connects RXP to RXN. These inputs are AC coupled on-chip with physical 220 nF capacitors. | | 11 | RX5P | B5 | Input | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting differential inputs to the equalizer. An on-chip 100-Ω termination resistor connects RXP to RXN. These inputs are AC coupled on-chip with physical 220 nF capacitors. | | 12 | RX5N | A5 | Input | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting differential inputs to the equalizer. An on-chip 100-Ω termination resistor connects RXP to RXN. These inputs are AC coupled on-chip with physical 220 nF capacitors. | | 13 | RX6P | B3 | Input | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting differential inputs to the equalizer. An on-chip 100-Ω termination resistor connects RXP to RXN. These inputs are AC coupled on-chip with physical 220 nF capacitors. | | 14 | RX6N | A3 | Input | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting differential inputs to the equalizer. An on-chip 100-Ω termination resistor connects RXP to RXN. These inputs are AC coupled on-chip with physical 220 nF capacitors. | | 15 | RX7P | C1 | Input | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting differential inputs to the equalizer. An on-chip 100-Ω termination resistor connects RXP to RXN. These inputs are AC coupled on-chip with physical 220 nF capacitors. | | 16 | RX7N | B1 | Input | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting differential inputs to the equalizer. An on-chip 100-Ω termination resistor connects RXP to RXN. These inputs are AC coupled on-chip with physical 220 nF capacitors. | | 17 | TX0P | G15 | Output | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting 50 Ω driver outputs. These outputs are AC coupled on-chip with physical 220 nF capacitors. | | 18 | TX0N | H15 | Output | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting 50 Ω driver outputs. These outputs are AC coupled on-chip with physical 220 nF capacitors. | | 19 | TX1P | H13 | Output | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting 50 Ω driver outputs. These outputs are AC coupled on-chip with physical 220 nF capacitors. | | 20 | TX1N | J13 | Output | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting 50 Ω driver outputs. These outputs are AC coupled on-chip with physical 220 nF capacitors. | | 21 | TX2P | H11 | Output | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting 50 Ω driver outputs. These outputs are AC coupled on-chip with physical 220 nF capacitors. | | 22 | TX2N | J11 | Output | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting 50 Ω driver outputs. These outputs are AC coupled on-chip with physical 220 nF capacitors. | | 23 | TX3P | H9 | Output | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting 50 Ω driver outputs. These outputs are AC coupled on-chip with physical 220 nF capacitors. | | 24 | TX3N | J9 | Output | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting 50 Ω driver outputs. These outputs are AC coupled on-chip with physical 220 nF capacitors. | | 25 | TX4P | H7 | Output | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting 50 Ω driver outputs. These outputs are AC coupled on-chip with physical 220 nF capacitors. | | 26 | TX4N | J7 | Output | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting 50 Ω driver outputs. These outputs are AC coupled on-chip with physical 220 nF capacitors. | | 27 | TX5P | H5 | Output | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting 50 Ω driver outputs. These outputs are AC coupled on-chip with physical 220 nF capacitors. | | 28 | TX5N | J5 | Output | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting 50 Ω driver outputs. These outputs are AC coupled on-chip with physical 220 nF capacitors. | | 29 | TX6P | H3 | Output | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting 50 Ω driver outputs. These outputs are AC coupled on-chip with physical 220 nF capacitors. | | 30 | TX6N | J3 | Output | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting 50 Ω driver outputs. These outputs are AC coupled on-chip with physical 220 nF capacitors. | | 31 | TX7P | G1 | Output | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting 50 Ω driver outputs. These outputs are AC coupled on-chip with physical 220 nF capacitors. | | 32 | TX7N | H1 | Output | | None | HIGH SPEED DIFFERENTIAL I/Os | Inverting and non-inverting 50 Ω driver outputs. These outputs are AC coupled on-chip with physical 220 nF capacitors. | | 33 | CAL_CLK_IN | E1 | Input | 2.5 V CMOS | Weak pull-down | CALIBRATION CLOCK PINS | 25 MHz (±100 PPM) 2.5 V single-ended clock from external oscillator. No stringent phase noise or jitter requirements on this clock. Used to calibrate VCO frequency range. This clock is not used to recover data. | | 34 | CAL_CLK_OUT | E15 | Output | 2.5 V CMOS | None | CALIBRATION CLOCK PINS | 2.5 V buffered replica of calibration clock input (pin E1) for connecting multiple devices in a daisy-chained fashion. | | 35 | ADDR0 | D13 | Input | 2.5 V 4-level | None | SYSTEM MANAGEMENT BUS (SMBUS) PINS | 4-level strap pins used to set the SMBus address of the device.\\ The pin state is read on power-up. The multi-level nature of these pins allows for 16 unique device addresses. The four strap options include:\\ 0: 1 kΩ to GND\\ R: 10 kΩ to GND\\ F: Float\\ 1: 1 kΩ to VDD\\ Refer to Device SMBus Address for more information. | | 36 | ADDR1 | E13 | Input | 2.5 V 4-level | None | SYSTEM MANAGEMENT BUS (SMBUS) PINS | 4-level strap pins used to set the SMBus address of the device.\\ The pin state is read on power-up. The multi-level nature of these pins allows for 16 unique device addresses. The four strap options include:\\ 0: 1 kΩ to GND\\ R: 10 kΩ to GND\\ F: Float\\ 1: 1 kΩ to VDD\\ Refer to Device SMBus Address for more information. | | 37 | EN_SMB | E3 | Input | 2.5 V 4-level | None | SYSTEM MANAGEMENT BUS (SMBUS) PINS | Four-level 2.5 V input used to select between SMBus master mode (float) and SMBus slave mode (high). The four defined levels are:\\ 0: 1 kΩ to GND - RESERVED, TI test mode.\\ R: 10 kΩ to GND - RESERVED, TI test mode\\ F: Float - SMBus Master Mode\\ 1: 1 kΩ to VDD - SMBus Slave Mode | | 38 | SDA | E12 | I/O | 3.3 V LVCMOS, Open Drain | None | SYSTEM MANAGEMENT BUS (SMBUS) PINS | SMBus data input and open drain output. External 2 kΩ to 5 kΩ pull-up resistor is required as per SMBus interface standard. This pin is 3.3 V LVCMOS tolerant. | | 39 | SDC | F12 | I/O | 3.3 V LVCMOS, Open Drain | None | SYSTEM MANAGEMENT BUS (SMBUS) PINS | SMBus clock input and open drain clock output. External 2 kΩ to 5 kΩ pull-up resistor is required as per SMBus interface standard. This pin is 3.3 V LVCMOS tolerant. | | 40 | READ_EN_N | F13 | Input | 3.3 V LVCMOS | Weak pull-up | SYSTEM MANAGEMENT BUS (SMBUS) PINS | SMBus Master Mode (EN_SMB=Float): When asserted low, initiates the SMBus master mode EEPROM read function. Once EEPROM read is complete (indicated by assertion of ALL_DONE_N low), this pin can be held low for normal device operation. This pin is 3.3 V tolerant.\\ SMBus Slave Mode (EN_SMB=1): When asserted low, this causes the device to be held in reset (I2C state machine reset and register reset). This pin should be pulled high or left floating for normal operation in SMBus Slave Mode. This pin is 3.3 V tolerant. | | 41 | ALL_DONE_N | D3 | Output | LVCMOS | None | SYSTEM MANAGEMENT BUS (SMBUS) PINS | Indicates the completion of a valid EEPROM register load operation when in SMBus Master Mode (EN_SMB=Float):\\ High = External EEPROM load failed or incomplete\\ Low = External EEPROM load successful and complete\\ When in SMBus slave mode (EN_SMB=1), this output reflects the status of READ_EN_N input. | | 42 | INT_N | F3 | Output | LVCMOS, Open-Drain | None | MISCELLANEOUS PINS | Open-drain 3.3 V tolerant active-low interrupt output. It pulls low when an interrupt occurs. The events which trigger an interrupt are programmable through SMBus registers. This pin can be connected in a wired-OR fashion with other device's interrupt pin. A single pull-up resistor in the 2 kΩ to 5 kΩ range is adequate for the entire INT_N net. | | 43 | TEST0 | E2 | Input | LVCMOS | Weak pull-up | MISCELLANEOUS PINS | Reserved TI test pins. During normal (non-test-mode) operation, these pins are configured as inputs and therefore they are not affected by the presence of a signal. These pins may be left floating, tied to GND, or connected to a 2.5-V (max) output. | | 44 | TEST1 | E14 | Input | LVCMOS | Weak pull-up | MISCELLANEOUS PINS | Reserved TI test pins. During normal (non-test-mode) operation, these pins are configured as inputs and therefore they are not affected by the presence of a signal. These pins may be left floating, tied to GND, or connected to a 2.5-V (max) output. | | 45 | TEST4 | F4 | Input | LVCMOS | Weak pull-up | MISCELLANEOUS PINS | Reserved TI test pin. During normal (non-test-mode) operation, this pin is configured as an input and therefore is not affected by the presence of a signal. This pin should be tied to GND or left floating. | | 46 | TEST5 | E4 | Input | LVCMOS | Weak pull-up | MISCELLANEOUS PINS | Reserved TI test pin. During normal (non-test-mode) operation, this pin is configured as an input and therefore is not affected by the presence of a signal. This pin may be left floating, tied to GND, or connected to a 2.5 V (max) output. | | 47 | TEST6 | D4 | Input | LVCMOS | Weak pull-up | MISCELLANEOUS PINS | Reserved TI test pin. During normal (non-test-mode) operation, this pin is configured as an input and therefore is not affected by the presence of a signal. This pin may be left floating, tied to GND, or connected to a 2.5 V (max) output. | | 48 | TEST7 | D12 | Input | LVCMOS | Weak pull-up | MISCELLANEOUS PINS | Reserved TI test pin. During normal (non-test-mode) operation, this pin is configured as an input and therefore is not affected by the presence of a signal. This pin may be left floating, tied to GND, or connected to a 2.5 V (max) output. | | 49 | VDD | D6 | Power | 2.5 V | None | POWER | Power supply, VDD = 2.5 V ±5%. TI recommends connecting at least six de-coupling capacitors between the Retimer’s VDD plane and GND as close to the Retimer as possible. For example, four 0.1 μF capacitors and two 1 μF capacitors directly beneath the device or as close to the VDD pins as possible. The VDD pins on this device should be connected through a lowresistance path to the board VDD plane. | | 50 | VDD | D8 | Power | 2.5 V | None | POWER | Power supply, VDD = 2.5 V ±5%. TI recommends connecting at least six de-coupling capacitors between the Retimer’s VDD plane and GND as close to the Retimer as possible. For example, four 0.1 μF capacitors and two 1 μF capacitors directly beneath the device or as close to the VDD pins as possible. The VDD pins on this device should be connected through a lowresistance path to the board VDD plane. | | 51 | VDD | D10 | Power | 2.5 V | None | POWER | Power supply, VDD = 2.5 V ±5%. TI recommends connecting at least six de-coupling capacitors between the Retimer’s VDD plane and GND as close to the Retimer as possible. For example, four 0.1 μF capacitors and two 1 μF capacitors directly beneath the device or as close to the VDD pins as possible. The VDD pins on this device should be connected through a lowresistance path to the board VDD plane. | | 52 | VDD | E5 | Power | 2.5 V | None | POWER | Power supply, VDD = 2.5 V ±5%. TI recommends connecting at least six de-coupling capacitors between the Retimer’s VDD plane and GND as close to the Retimer as possible. For example, four 0.1 μF capacitors and two 1 μF capacitors directly beneath the device or as close to the VDD pins as possible. The VDD pins on this device should be connected through a lowresistance path to the board VDD plane. | | 53 | VDD | E6 | Power | 2.5 V | None | POWER | Power supply, VDD = 2.5 V ±5%. TI recommends connecting at least six de-coupling capacitors between the Retimer’s VDD plane and GND as close to the Retimer as possible. For example, four 0.1 μF capacitors and two 1 μF capacitors directly beneath the device or as close to the VDD pins as possible. The VDD pins on this device should be connected through a lowresistance path to the board VDD plane. | | 54 | VDD | E7 | Power | 2.5 V | None | POWER | Power supply, VDD = 2.5 V ±5%. TI recommends connecting at least six de-coupling capacitors between the Retimer’s VDD plane and GND as close to the Retimer as possible. For example, four 0.1 μF capacitors and two 1 μF capacitors directly beneath the device or as close to the VDD pins as possible. The VDD pins on this device should be connected through a lowresistance path to the board VDD plane. | | 55 | VDD | E8 | Power | 2.5 V | None | POWER | Power supply, VDD = 2.5 V ±5%. TI recommends connecting at least six de-coupling capacitors between the Retimer’s VDD plane and GND as close to the Retimer as possible. For example, four 0.1 μF capacitors and two 1 μF capacitors directly beneath the device or as close to the VDD pins as possible. The VDD pins on this device should be connected through a lowresistance path to the board VDD plane. | | 56 | VDD | E9 | Power | 2.5 V | None | POWER | Power supply, VDD = 2.5 V ±5%. TI recommends connecting at least six de-coupling capacitors between the Retimer’s VDD plane and GND as close to the Retimer as possible. For example, four 0.1 μF capacitors and two 1 μF capacitors directly beneath the device or as close to the VDD pins as possible. The VDD pins on this device should be connected through a lowresistance path to the board VDD plane. | | 57 | VDD | E10 | Power | 2.5 V | None | POWER | Power supply, VDD = 2.5 V ±5%. TI recommends connecting at least six de-coupling capacitors between the Retimer’s VDD plane and GND as close to the Retimer as possible. For example, four 0.1 μF capacitors and two 1 μF capacitors directly beneath the device or as close to the VDD pins as possible. The VDD pins on this device should be connected through a lowresistance path to the board VDD plane. | | 58 | VDD | F6 | Power | 2.5 V | None | POWER | Power supply, VDD = 2.5 V ±5%. TI recommends connecting at least six de-coupling capacitors between the Retimer’s VDD plane and GND as close to the Retimer as possible. For example, four 0.1 μF capacitors and two 1 μF capacitors directly beneath the device or as close to the VDD pins as possible. The VDD pins on this device should be connected through a lowresistance path to the board VDD plane. | | 59 | VDD | F8 | Power | 2.5 V | None | POWER | Power supply, VDD = 2.5 V ±5%. TI recommends connecting at least six de-coupling capacitors between the Retimer’s VDD plane and GND as close to the Retimer as possible. For example, four 0.1 μF capacitors and two 1 μF capacitors directly beneath the device or as close to the VDD pins as possible. The VDD pins on this device should be connected through a lowresistance path to the board VDD plane. | | 60 | VDD | F10 | Power | 2.5 V | None | POWER | Power supply, VDD = 2.5 V ±5%. TI recommends connecting at least six de-coupling capacitors between the Retimer’s VDD plane and GND as close to the Retimer as possible. For example, four 0.1 μF capacitors and two 1 μF capacitors directly beneath the device or as close to the VDD pins as possible. The VDD pins on this device should be connected through a lowresistance path to the board VDD plane. | | 61 | GND | A1 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 62 | GND | A2 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 63 | GND | A4 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 64 | GND | A6 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 65 | GND | A8 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 66 | GND | A10 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 67 | GND | A12 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 68 | GND | A14 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 69 | GND | A15 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 70 | GND | B2 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 71 | GND | B4 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 72 | GND | B6 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 73 | GND | B8 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 74 | GND | B10 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 75 | GND | B12 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 76 | GND | B14 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 77 | GND | C2 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 78 | GND | C3 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 79 | GND | C4 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 80 | GND | C5 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 81 | GND | C6 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 82 | GND | C7 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 83 | GND | C8 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 84 | GND | C9 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 85 | GND | C10 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 86 | GND | C11 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 87 | GND | C12 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 88 | GND | C13 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 89 | GND | C14 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 90 | GND | D1 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 91 | GND | D2 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 92 | GND | D5 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 93 | GND | D7 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 94 | GND | D9 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 95 | GND | D11 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 96 | GND | D14 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 97 | GND | D15 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 98 | GND | E11 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 99 | GND | F1 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 100 | GND | F2 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 101 | GND | F5 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 102 | GND | F7 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 103 | GND | F9 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 104 | GND | F11 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 105 | GND | F14 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 106 | GND | F15 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 107 | GND | G2 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 108 | GND | G3 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 109 | GND | G4 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 110 | GND | G5 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 111 | GND | G6 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 112 | GND | G7 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 113 | GND | G8 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 114 | GND | G9 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 115 | GND | G10 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 116 | GND | G11 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 117 | GND | G12 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 118 | GND | G13 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 119 | GND | G14 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 120 | GND | H2 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 121 | GND | H4 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 122 | GND | H6 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 123 | GND | H8 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 124 | GND | H10 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 125 | GND | H12 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 126 | GND | H14 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 127 | GND | J1 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 128 | GND | J2 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 129 | GND | J4 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 130 | GND | J6 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 131 | GND | J8 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 132 | GND | J10 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 133 | GND | J12 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 134 | GND | J14 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. | | 135 | GND | J15 | Power | | None | POWER | Ground reference. The GND pins on this device should be connected through a low-resistance path to the board GND plane. |