DS100KR401 Ultra Low Power, 4 Lane (8-channel, bi-directional) Repeater for Data-rates up to 10.3 Gbps automatically loaded on power up. This eliminates the need for an external microprocessor or software driver. General Description The DS100KR401 is an extremely low power, high performance repeater designed to support 4 lane (bi-directional) 10G-KR and other high speed interface serial protocols up to 10.3 Gbps. The receiver's continuous time linear equalizer (CTLE) provides a boost of up to +36 dB at 5 GHz (10.3125 Gbps) in each of its eight channels and is capable of opening an input eye that is completely closed due to inter symbol interference (ISI) induced by interconnect medium such as long backplanes or cables, hence enabling host controllers to ensure an error free end-to-end link. The transmitter provides a de-emphasis boost of up to -12 dB and output voltage amplitude control from 700 mV to 1300 mV to allow maximum flexibility in the physical placement within the interconnect channel. When operating in 10G-KR mode, the DS100KR401 transparently allows the host controller and the end point to optimize the full link and negotiate transmit equalizer coefficients as defined in the 802.3ap standard. This seamless management of the link training protocol ensures guaranteed system level interoperability with minimum latency. With a low power consumption of 65 mW/channel (typ) and option to turn-off unused channels, the DS100KR401 enables energy efficient system design. A single supply of 3.3v or 2.5v is required to power the device. The programmable settings can be applied via pin settings, SMBus (I2C) protocol or an external EEPROM. When operating in the EEPROM mode, the configuration information is Features ■ Comprehensive product family: ■ ■ ■ ■ ■ ■ ■ ■ ■ DS100KR800: 8-channel, uni-directional repeater DS100KR401: 4x lane, bi-directional repeater DS100BR210: 2-channel, uni-directional repeater DS100BR111: 1x lane, bi-directional repeater 4 lane (8-channel, bi-directional) repeater for 4x 10G-KR and other serial standards up to 10.3 Gbps Transparent management of 10G-KR (802.3ap) link training protocol Low 65 mW/channel (typ) power consumption, with option to power down unused channels Advanced signal conditioning features - Receive Equalization up to 36 dB at 5 GHz - Transmit de-emphasis up to -12 dB - Transmit output voltage control: 700 mV to 1300 mV Programmable via pin selection, EEPROM or SMBus interface Single supply operation selectable: 2.5V or 3.3V -40˚ to +85˚C operating temperature range 3 kV HBM ESD rating Flow-thru pinout in 10mmx5.5mm 54-pin leadless LLP package Typical Application 30147980 © 2012 Texas Instruments Incorporated 301479 SNLS395B www.ti.com DS100KR401 Ultra Low Power, 4 Lane (8-channel, bi-directional) Repeater for Data-rates up to 10.3 Gbps March 22, 2012 DS100KR401 Block Diagram - Detail View Of Channel (1 Of 8) 30147986 www.ti.com 2 DS100KR401 Pin Diagram 30147992 DS100KR401 Pin Diagram 54 lead Ordering Information NSID Qty Spec Package DS100KR401SQ Tape & Reel Supplied As 2,000 Units NOPB SQA54A DS100KR401SQE Tape & Reel Supplied As 250 Units NOPB SQA54A 3 www.ti.com DS100KR401 Pin Descriptions Pin Name Pin Number I/O, Type Pin Description Differential High Speed I/O's OUT_B_0+, OUT_B_0-, OUT_B_1+, OUT_B_1-, OUT_B_2+, OUT_B_2-, OUT_B_3+, OUT_B_3- 1, 2, 3, 4, 5, 6, 7, 8 O Inverting and non-inverting 50Ω driver bank B outputs with deemphasis. Compatible with AC coupled CML inputs. IN_A_0+, IN_A_0-, IN_A_1+, IN_A_1-, IN_A_2+, IN_A_2-, IN_A_3+, IN_A_3- 10, 11, 12, 13, 15, 16, 17, 18 I Inverting and non-inverting differential inputs to bank A equalizer. A gated on-chip 50Ω termination resistor connects INA_n+ to VDD and INA_n- to VDD when enabled. IN_B_0+, IN_B_0-, IN_B_1+, IN_B_1-, IN_B_2+, IN_B_2-, IN_B_3+, IN_B_3- 45, 44, 43, 42, 40, 39, 38, 37 I Inverting and non-inverting differential inputs to bank B equalizer. A gated on-chip 50Ω termination resistor connects INB_n+ to VDD and INB_n- to VDD when enabled. OUT_A_0+, OUT_A_0-, OUT_A_1+, OUT_A_1-, OUT_A_2+, OUT_A_2-, OUT_A_3+, OUT_A_3- 35, 34, 33, 32, 31, 30, 29, 28 O Inverting and non-inverting 50Ω driver bank A outputs with deemphasis. Compatible with AC coupled CML inputs. I, LVCMOS System Management Bus (SMBus) enable pin Control Pins — Shared (LVCMOS) ENSMB 48 Tie 1kΩ to VDD = Register Access SMBus Slave mode FLOAT = Read External EEPROM (Master SMBUS Mode) Tie 1kΩ to GND = Pin Mode ENSMB = 1 (SMBUS MODE) SCL 50 I, LVCMOS, O, OPEN Drain ENSMB Master or Slave mode SMBUS clock input pin is enabled. Clock output when loading EEPROM configuration (master mode). SDA 49 I, LVCMOS, O, OPEN Drain ENSMB Master or Slave mode The SMBus bi-directional SDA pin is enabled. Data input or open drain (pull-down only) output. AD0-AD3 54, 53, 47, 46 I, LVCMOS ENSMB Master or Slave mode SMBus Slave Address Inputs. In SMBus mode, these pins are the user set SMBus slave address inputs. READ_EN 26 I, 4-LEVEL, LVCMOS When using an External EEPROM, a transition from high to low starts the load from the external EEPROM 20, 19, 46, 47 I, 4-LEVEL, LVCMOS EQA[1:0] and EQB[1:0] control the level of equalization on the input pins. The pins are active only when ENSMB is deasserted (low). The 8 channels are organized into two banks. Bank A is controlled with the EQA[1:0] pins and bank B is controlled with the EQB[1:0] pins. When ENSMB is high the SMBus registers provide independent control of each channel. The EQB[1:0] pins are converted to SMBUS AD2/ AD3 inputs. See Table 2 ENSMB = 0 (PIN MODE) EQA0, EQA1, EQB0, EQB1 www.ti.com 4 Pin Number I/O, Type Pin Description DEMA0, DEMA1, DEMB0, DEMB1 49, 50, 53, 54 I, 4-LEVEL, LVCMOS DEMA[1:0] and DEMB[1:0] control the level of de-emphasis of the output driver when in Gen1/2 mode. The pins are only active when ENSMB is de-asserted (low). The 8 channels are organized into two banks. Bank A is controlled with the DEMA [1:0] pins and bank B is controlled with the DEMB[1:0] pins. When ENSMB is high the SMBus registers provide independent control of each channel. The DEMA[1:0] pins are converted to SMBUS SCL/SDA and DEMB[1:0] pins are converted to AD0, AD1 inputs. See Table 3 MODE 21 I, 4-LEVEL, LVCMOS Tie 1kΩ to VDD = 10G-KR Mode Operation Tie 1kΩ to GND = 10G Mode Operation SD_TH 26 I, 4-LEVEL, LVCMOS Controls the internal Signal Detect Threshold See Table 4 Control Pins — Both Pin and SMBus Modes (LVCMOS) INPUT_EN 22 I, 4-LEVEL, LVCMOS Tie 1kΩ to VDD = Normal Operation LPBK 23 I, 4-LEVEL, LVCMOS Controls the loopback function Tie 1kΩ to GND = INA_n to OUTB_n loopback Float = Normal Operation (loopback is disabled) Tie 1kΩ to VDD = INB_n to OUTA_n loopback VDD_SEL 25 I, FLOAT Controls the internal regulator RESET 52 I, LVCMOS 27 O, LVCMOS Float = 2.5V mode Tie GND = 3.3V mode LOW = Device is enabled (Normal Operation) HIGH = Low Power Mode Outputs ALL_DONE Valid Register Load Status Output HIGH = External EEPROM load failed LOW = External EEPROM load passed Power VIN 24 Power VDD 9, 14, 36, 41, 51 Power In 3.3V mode, feed 3.3V to VIN In 2.5V mode, leave floating. Power supply pins CML/analog 2.5V mode, connect to 2.5V 3.3V mode, connect 0.1 uF cap to each VDD pin GND DAP Power Ground pad (DAP - die attach pad). Notes: LVCMOS inputs without the “Float” conditions must be driven to a logic low or high at all times or operation is not guaranteed. Input edge rate for LVCMOS/FLOAT inputs must be faster than 50 ns from 10–90%. For 3.3V mode operation, VIN pin = 3.3V and the "VDD" for the 4-level input is 3.3V. For 2.5V mode operation, VDD pin = 2.5V and the "VDD" for the 4-level input is 2.5V. 5 www.ti.com DS100KR401 Pin Name DS100KR401 HBM, STD - JESD22-A114F MM, STD - JESD22-A115-A CDM, STD - JESD22-C101-D Thermal Resistance Absolute Maximum Ratings (Note 1) If Military/Aerospace specified devices are required, please contact the Texas Instruments Sales Office/ Distributors for availability and specifications. Supply Voltage (VDD = 2.5V mode) Supply Voltage (VIN = 3.3V mode) LVCMOS Input/Output Voltage CML Input Voltage CML Input Current Junction Temperature Storage Temperature Lead Temperature Range Soldering (4 sec.) Derate SQA54A Package θJC -0.5V to +2.75V -0.5V to +4.0V -0.5V to +4.0V -0.5V to (VDD+0.5) -30 to +30 mA 125°C -40°C to +125°C +260°C Supply Voltage (2.5V mode) Supply Voltgae (3.3V mode) Ambient Temperature SMBus (SDA, SCL) Supply Noise up to 50 MHz (Note 4) 52.6mW/°C above +25°C Parameter Conditions Power Dissipation 11.5°C/W 19.1°C/W θJA, No Airflow, 4 layer JEDEC For soldering specifications: see product folder at www.national.com www.national.com/ms/MS/MSSOLDERING.pdf ESD Rating Symbol 5 kV 150 V 1000 V Min Min 2.375 3.0 -40 Typ 2.5 3.3 25 Max 2.625 3.6 +85 3.6 100 Units V V °C V mVp-p Typ Max Units VDD = 2.5 V supply, EQ Enabled, VOD = 1.0 Vp-p, INPUT_EN = 1, RESET = 0 500 700 mW VIN = 3.3 V supply, EQ Enabled, VOD = 1.0 Vp-p, INPUT_EN = 1, RESET = 0 660 900 mW 2.0 3.6 V 0 0.8 V Power PD LVCMOS / LVTTL DC Specifications Vih High Level Input Voltage Vil Low Level Input Voltage Voh High Level Output Voltage (ALL_DONE pin) Ioh = −4mA Low Level Output Voltage (ALL_DONE pin) Iol = 4mA Input High Current (RESET pin) VIN = 3.6 V, LVCMOS = 3.6 V Vol Iih 3.3V Mode Operation (VIN = 3.3V) 2.0 Input High Current with internal resistors (4–level input pin) Iil Input Low Current (RESET pin) VIN = 3.6 V, LVCMOS = 0 V Input Low Current with internal resistors (4–level input pin) www.ti.com 6 V 0.4 V -15 +15 uA +20 +150 uA -15 +15 uA -160 -40 uA Parameter Conditions Min Typ Max Units CML Receiver Inputs (IN_n+, IN_n-) RLrx-diff RX package pins plus Si differential return loss 0.05 GHz - 7.5 GHz RLrx-cm Common mode RX return loss 0.05 GHz - 5 GHz Zrx-dc RX DC common mode Tested at VDD = 0 impedance 40 50 60 Ω Zrx-diff-dc RX DC differntial mode Tested at VDD = 0 impedance 80 100 120 Ω Vrx-diff-dc Differential RX peak to Tested at pins peak voltage 0.6 1.2 V Vrx-signal-detdiff-pp Signal detect assert level for active data signal SD_TH = F (float), 0101 pattern at 10.3 Gbps 180 mVp-p Vrx-idle-detdiff-pp Signal detect de-assert SD_TH = F (float), level for electrical idle 0101 pattern at 10.3 Gbps 110 mVp-p 7.5 GHz - 15 GHz -15 dB -5 dB -10 dB High Speed Outputs Vtx-diff-pp Vtx-de-ratio_3.5 Output Voltage Differential Swing TXde-emphasis ratio Differential measurement with Out_n+ and OUT_n-, terminated by 50Ω to GND, AC-Coupled, VID = 1.0 Vp-p, DEM0 = 1, DEM1 = 0 0.8 VOD = 1.0 Vp-p, DEM0 = 0, DEM1 = R VOD = 1.0 Vp-p, DEM0 = R, DEM1= R 1.0 1.2 Vp-p −3.5 dB −6 dB Vtx-de-ratio_6 TX de-emphasis ratio TTX-HF-DJ-DD TX Dj > 1.5 MHz TTX-HF-DJ-DD TX RMS jitter < 1.5 MHz TTX-RISE-FALL Transmitter rise/fall time 20% to 80% of differential output voltage TRF-MISMATCH Transmitter rise/fall mismatch 20% to 80% of differential output voltage 0.01 RLTX-DIFF Differential return loss 0.05 GHz - 7.5 GHz -15 dB 7.5 GHz - 15 GHz -5 dB -10 dB 100 Ω 0.05 GHz - 5 GHz 35 0.15 UI 3.0 ps RMS 45 ps 0.1 UI RLTX-CM Common mode return loss ZTX-DIFF-DC DC differential TX impedance VTX-CM-AC-PP TX AC common mode voltage ITX-SHORT Transmitter short circuit Total current the transmitter current limit can supply when shorted to VDD or GND 20 mA TPDEQ Differential propagation EQ = 00, (Note 6) delay 200 ps TLSK Lane to lane skew T = 25C, VDD = 2.5V 25 ps TPPSK Part to part propagation T = 25C, VDD = 2.5V delay skew 40 ps VOD = 1.0 Vp-p, DEM0 = 1, DEM1 = 0 100 7 mVpp www.ti.com DS100KR401 Symbol DS100KR401 Symbol Parameter Conditions Min Typ Max Units Residual deterministic jitter at 10.3 Gbps 35” 4 mil FR4, VID = 0.8 Vp-p, PRBS15, EQ = 1F'h, DEM = 0 dB 0.3 UI Residual deterministic jitter at 10.3 Gbps 10 meters 30 awg cable, VID = 0.8 Vp-p, PRBS15, EQ = 2F'h, DEM = 0 dB 0.3 UI Residual deterministic jitter at 10.3 Gbps 20” 4mils FR4, VID = 0.8 Vp-p, PRBS15, EQ = 00, VOD = 1.0 Vp-p, DEM = −9 dB 0.1 UI Equalization DJE1 DJE2 De-emphasis DJD1 Note 1: “Absolute Maximum Ratings” indicate limits beyond which damage to the device may occur, including inoperability and degradation of device reliability and/or performance. Functional operation of the device and/or non-degradation at the Absolute Maximum Ratings or other conditions beyond those indicated in the Recommended Operating Conditions is not implied. The Recommended Operating Conditions indicate conditions at which the device is functional and the device should not be operated beyond such conditions. Absolute Maximum Numbers are guaranteed for a junction temperature range of -40°C to +125°C. Models are validated to Maximum Operating Voltages only. Note 2: Typical values represent most likely parametric norms at VDD = 2.5V, TA = 25°C., and at the Recommended Operation Conditions at the time of product characterization and are not guaranteed. Note 3: The Electrical Characteristics tables list guaranteed specifications under the listed Recommended Operating Conditions except as otherwise modified or specified by the Electrical Characteristics Conditions and/or Notes. Typical specifications are estimations only and are not guaranteed. Note 4: Allowed supply noise (mVp-p sine wave) under typical conditions. Note 5: Guaranteed by device characterization. Note 6: Propagation Delay measurements will change slightly based on the level of EQ selected. EQ = 00 will result in the shortest propagation delays. www.ti.com 8 Over recommended operating supply and temperature ranges unless other specified. Symbol Parameter Conditions Min Typ Max Units 0.8 V 3.6 V SERIAL BUS INTERFACE DC SPECIFICATIONS VIL Data, Clock Input Low Voltage VIH Data, Clock Input High Voltage IPULLUP Current Through Pull-Up Resistor High Power Specification or Current Source VDD Nominal Bus Voltage ILEAK-Bus Input Leakage Per Bus Segment ILEAK-Pin Input Leakage Per Device Pin CI Capacitance for SDA and SCL RTERM External Termination Resistance Pullup VDD = 3.3V, pull to VDD = 2.5V ± 5% OR 3.3V ± (Note 7, Note 8, Note 9) 10% Pullup VDD = 2.5V, (Note 7, Note 8, Note 9) 2.1 (Note 7) 4 mA 2.375 3.6 V -200 +200 µA -15 (Note 7, Note 8) µA 10 pF 2000 Ω 1000 Ω SERIAL BUS INTERFACE TIMING SPECIFICATIONS FSMB Bus Operating Frequency ENSMB = VDD (Slave Mode) ENSMB = FLOAT (Master Mode) 280 400 400 kHz 520 kHz TBUF Bus Free Time Between Stop and Start Condition 1.3 µs THD:STA Hold time after (Repeated) Start At IPULLUP, Max Condition. After this period, the first clock is generated. 0.6 µs TSU:STA Repeated Start Condition Setup Time 0.6 µs TSU:STO Stop Condition Setup Time 0.6 µs THD:DAT Data Hold Time 0 ns TSU:DAT Data Setup Time 100 ns TLOW Clock Low Period THIGH Clock High Period (Note 10) tF Clock/Data Fall Time tR Clock/Data Rise Time tPOR Time in which a device must be operational after power-on reset (Note 10, Note 11) 1.3 0.6 µs 50 µs (Note 10) 300 ns (Note 10) 300 ns 500 ms Note 7: Recommended value. Note 8: Recommended maximum capacitance load per bus segment is 400pF. Note 9: Maximum termination voltage should be identical to the device supply voltage. Note 10: Compliant to SMBus 2.0 physical layer specification. See System Management Bus (SMBus) Specification Version 2.0, section 3.1.1 SMBus common AC specifications for details. Note 11: Guaranteed by Design. Parameter not tested in production. 9 www.ti.com DS100KR401 Electrical Characteristics — Serial Management Bus Interface DS100KR401 Timing Diagrams 30147902 FIGURE 1. CML Output and Rise and FALL Transition Time 30147903 FIGURE 2. Propagation Delay Timing Diagram 30147905 FIGURE 3. SMBus Timing Parameters www.ti.com 10 The DS100KR401 is a low power media compensation 4 lane repeater optimized for 10G–KR. The DS100KR401 compensates for lossy FR-4 printed circuit board backplanes and balanced cables. The DS100KR401 operates in 3 modes: Pin Control Mode (ENSMB = 0), SMBus Slave Mode (ENSMB = 1) and SMBus Master Mode (ENSMB = float) to load register informations from external EEPROM; please refer to SMBUS Master Mode for additional information. Pin Control Mode: When in pin mode (ENSMB = 0) , the repeater is configurable with external pins. Equalization and de-emphasis can be selected via pin for each side independently. When de-emphasis is asserted VOD is automatically adjusted per the DeEmphasis table below. The receiver electrical idle detect threshold is also adjustable via the SD_TH pin. SMBUS Mode: When in SMBus mode (ENSMB = 1), the VOD (output amplitude), equalization, de-emphasis, and termination disable features are all programmable on a individual lane basis, instead of grouped by A or B as in the pin mode case. Upon assertion of ENSMB the MODE, EQx and DEMx functions revert to register control immediately. The EQx and DEMx pins are converted to AD0-AD3 SMBus address inputs. The other external control pins remain active unless their respective registers are written to and the appropriate override bit is set, in which case they are ignored until ENSMB is driven low (pin mode). On power-up and when ENSMB is driven low all registers are reset to their default state. If RESET is asserted while ENSMB is high, the registers retain their current state. Equalization settings accessible via the pin controls were chosen to meet the needs of most applications. If additional fine tuning or adjustment is needed, additional equalization settings can be accessed via the SMBus registers. Each input has a total of 256 possible equalization settings. The tables TABLE 1. 4–Level Control Pin Settings Pin Setting Description Voltage at Pin 0 Tie 1kΩ to GND 0.03 x VDD R Tie 20kΩ to GND 1/3 x VDD Float Float (leave pin open) 2/3 x VDD 1 Tie 1kΩ to VDD 0.98 x VDD Note: The above required resistor value is for a single device. When there are multiple devices connected to the pull-up / pull-down resistor, the value must scale with the number of devices. If 4 devices are connected to a single pull-up or pull-down, the 1kΩ resistor value should be 250Ω. For the 20kΩ to GND, this should also scale to 5kΩ. 3.3V or 2.5V Supply Mode Operation The DS100KR401 has an optional internal voltage regulator to provide the 2.5V supply to the device. In 3.3V mode, the VIN pin = 3.3V is used to supply power to the device and the VDD pins should be left open. The internal regulator will provide the 2.5V to the VDD pins of the device and a 0.1 uF cap is needed at each of 5 VDD pins for power supply de-coupling (total capacitance should be ≤0.5 uF). The VDD_SEL pin must be tied to GND to enable the internal regulator. In 2.5V mode, the VIN pin should be left open and 2.5V supply must be applied to the VDD pins. The VDD_SEL pin must be left open (no connect) to disable the internal regulator. 11 www.ti.com DS100KR401 show the 16 setting when the device is in pin mode. When using SMBus mode, the equalization, VOD and de-Emphasis levels are set by registers. The input control pins have been enhanced to have 4 different levels and provide a wider range of control settings when ENSMB=0. Functional Descriptions DS100KR401 30147906 FIGURE 4. 3.3V or 2.5V Supply Connection Diagram TABLE 2. Equalizer Settings Level EQA1 EQB1 EQA0 EQB0 EQ – 8 bits [7:0] dB at 1.0 GHz dB at 3.0 GHz dB at 5.0 GHz 1 2 3 0 0 0000 0000 = 0x00 1.7 4.2 5.3 FR4 < 5 inch trace 0 R 0000 0001 = 0x01 2.8 6.6 8.7 FR4 5 inch 5–mil trace 0 Float 0000 0010 = 0x02 4.1 8.6 10.6 FR4 5 inch 4–mil trace 4 0 1 0000 0011 = 0x03 5.1 9.8 11.7 FR4 10 inch 5–mil trace 5 R 0 0000 0111 = 0x07 6.2 12.4 15.6 FR4 10 inch 4–mil trace 6 R R 0001 0101 = 0x15 5.1 12.0 16.6 FR4 15 inch 4–mil trace 7 R Float 0000 1011 = 0x0B 7.7 15.0 18.3 FR4 20 inch 4–mil trace 8 R 1 0000 1111 = 0x0F 8.8 16.5 19.7 FR4 25 to 30 inch 4–mil trace 9 Float 0 0101 0101 = 0x55 6.3 14.8 20.3 FR4 30 inch 4–mil trace 10 Float R 0001 1111 = 0x1F 9.9 19.2 23.6 FR4 35 inch 4–mil trace 11 Float Float 0010 1111 = 0x2F 11.3 21.7 25.8 10m, 30awg cable 12 Float 1 0011 1111 = 0x3F 12.4 23.2 27.0 10m – 12m cable 13 1 0 1010 1010 = 0xAA 11.9 24.1 29.1 14 1 R 0111 1111 = 0x7F 13.6 26.0 30.7 15 1 Float 1011 1111 = 0xBF 15.1 28.3 32.7 16 1 1 1111 1111 = 0xFF 16.1 29.7 33.8 www.ti.com 12 Suggested Use DS100KR401 TABLE 3. De-emphasis and Output Voltage Settings Level DEMA1 DEMB1 DEMA0 DEMB0 VOD Vp-p DEM dB Inner Amplitude Vp-p Suggested Use 1 0 0 0.8 0 0.8 FR4 <5 inch 4–mil trace 2 0 R 0.9 0 0.9 FR4 <5 inch 4–mil trace 3 0 Float 0.9 - 3.5 0.6 FR4 10 inch 4–mil trace 4 0 1 1.0 0 1.0 FR4 <5 inch 4–mil trace 5 R 0 1.0 - 3.5 0.7 FR4 10 inch 4–mil trace 6 R R 1.0 -6 0.5 FR4 15 inch 4–mil trace 7 R Float 1.1 0 1.1 FR4 <5 inch 4–mil trace 8 R 1 1.1 - 3.5 0.7 FR4 10 inch 4–mil trace 9 Float 0 1.1 -6 0.6 FR4 15 inch 4–mil trace 10 Float R 1.2 0 1.2 FR4 <5 inch 4–mil trace 11 Float Float 1.2 - 3.5 0.8 FR4 10 inch 4–mil trace 12 Float 1 1.2 -6 0.6 FR4 15 inch 4–mil trace 13 1 0 1.3 0 1.3 FR4 <5 inch 4–mil trace 14 1 R 1.3 - 3.5 0.9 FR4 10 inch 4–mil trace 15 1 Float 1.3 -6 0.7 FR4 15 inch 4–mil trace 16 1 1 1.3 -9 0.5 FR4 20 inch 4–mil trace 13 www.ti.com DS100KR401 TABLE 4. Signal Detect Threshold Level SD_TH SMBus REG bit [3:2] and [1:0] Assert Level (typ) De-assert Level (typ) 0 10 210 mVp-p 150 mVp-p R 01 160 mVp-p 100 mVp-p F (default) 00 180 mVp-p 110 mVp-p 1 11 190 mVp-p 130 mVp-p Note: VDD = 2.5V, 25°C and 0101 pattern at 10.3 Gbps SMBUS Master Mode The DS100KR401 devices support reading directly from an external EEPROM device by implementing SMBus Master mode. When using the SMBus master mode, the DS100KR401 will read directly from specific location in the external EEPROM. When designing a system for using the external EEPROM, the user needs to follow these specific guidelines. • • • Set ENSMB = Float — enable the SMBUS master mode. The external EEPROM device address byte must be 0xA0'h and capable of 400 kHz operation at 2.5V and 3.3V supply. Set the AD[3:0] inputs for SMBus address byte. When the AD[3:0] = 0000'b, the device address byte is B0'h. When tying multiple DS100KR401 devices to the SDA and SCL bus, use these guidelines to configure the devices. • • • Use SMBus AD[3:0] address bits so that each device can loaded it's configuration from the EEPROM. Example below is for 4 device. U1: AD[3:0] = 0000 = 0xB0'h, U2: AD[3:0] = 0001 = 0xB2'h, U3: AD[3:0] = 0010 = 0xB4'h, U4: AD[3:0] = 0011 = 0xB6'h Use a pull-up resistor on SDA and SCL; value = 2k ohms Daisy-chain READEN# (pin 26) and ALL_DONE# (pin 27) from one device to the next device in the sequence so that they do not compete for the EEPROM at the same time. 1. Tie READEN# of the 1st device in the chain (U1) to GND 2. Tie ALL_DONE# of U1 to READEN# of U2 3. Tie ALL_DONE# of U2 to READEN# of U3 4. Tie ALL_DONE# of U3 to READEN# of U4 5. Optional: Tie ALL_DONE# output of U4 to a LED to show the devices have been loaded successfully Below is an example of a 2 kbits (256 x 8-bit) EEPROM in hex format for the DS100KR401 device. The first 3 bytes of the EEPROM always contain a header common and necessary to control initialization of all devices connected to the I2C bus. CRC enable flag to enable/disable CRC checking. If CRC checking is disabled, a fixed pattern (8’hA5) is written/read instead of the CRC byte from the CRC location, to simplify the control. There is a MAP bit to flag the presence of an address map that specifies the configuration data start in the EEPROM. If the MAP bit is not present the configuration data start address is derived from the DS100KR401 address and the configuration data size. A bit to indicate an EEPROM size > 256 bytes is necessary to properly address the EEPROM. There are 37 bytes of data size for each DS100KR401 device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www.ti.com 14 CRC EN Description 0 ch1_idle_tha_1 14 Description Value 1 ch1_RES_0 Value 1 Description 13 Value ch1_BST_3 Description 12 0 ch1_Idle_auto 11 Description Value 0 ch0_DEM_2 Value 1 Description 10 Value ch0_Sel_scp Description 9 0 ch0_BST_7 Value 0 8 Description RD_delay_sel_3 Description Value 0 Value 7 Ovrd_RES Description 6 0 RES Value 0 Description 5 Value RES_1 Description 4 0 PWDN_ch7 Value 0 Description 3 Value Max EEPROM Burst size[7] Description 2 0 RES 1 Description Value 0 Value 0 Bit 7 EEPROM Address Byte 0 ch1_idle_tha_0 1 ch1_VOD_2 1 ch1_BST_2 0 ch1_Idle_sel 1 ch0_DEM_1 0 ch0_Sel_mode 0 ch0_BST_6 0 RD_delay_sel_2 0 Ovrd_RES 0 RES 0 RES_0 0 PWDN_ch6 0 Max EEPROM Burst size[6] 0 RES 0 Address Map Present Bit 6 0 ch1_idle_thd_1 0 ch1_VOD_1 1 ch1_BST_1 0 ch1_RES_1 0 ch0_DEM_0 1 ch0_RES_2 1 ch0_BST_5 0 RD_delay_sel_1 0 Ovrd_RES 0 RES 0 PWDN_INPUTS 0 PWDN_ch5 0 Max EEPROM Burst size[5] 0 RES 0 EEPROM > 256 Bytes Bit 5 0 ch1_idle_thd_0 1 ch1_VOD_0 1 ch1_BST_0 0 ch1_RES_0 0 ch0_Slow 0 ch0_RES_1 0 ch0_BST_4 0 RD_delay_sel_0 0 Ovrd_RES 0 RES 0 PWDN_OSC 0 PWDN_ch4 0 Max EEPROM Burst size[4] 0 RES 0 RES Bit 4 0 ch2_Idle_auto 0 ch1_DEM_2 1 ch1_Sel_scp 0 ch1_BST_7 0 ch0_idle_tha_1 1 ch0_RES_0 1 ch0_BST_3 0 ch0_Idle_auto 0 Ovrd_RES 0 RES 0 Ovrd_RESET 0 PWDN_ch3 0 Max EEPROM Burst size[3] 0 RES 0 DEVICE COUNT [3] Bit 3 TABLE 5. EEPROM Register Map - Single Device with Default Value 0 ch2_Idle_sel 1 ch1_DEM_1 0 ch1_Sel_mode 0 ch1_BST_6 0 ch0_idle_tha_0 1 ch0_VOD_2 1 ch0_BST_2 0 ch0_Idle_sel 1 rx_delay_sel_2 1 RES_btb_en 0 RES 0 PWDN_ch2 0 Max EEPROM Burst size[2] 0 RES 0 DEVICE COUNT [2] Bit 2 0 ch2_RES_1 0 ch1_DEM_0 1 ch1_RES_2 1 ch1_BST_5 0 ch0_idle_thd_1 0 ch0_VOD_1 1 ch0_BST_1 0 ch0_RES_1 1 rx_delay_sel_1 0 Ovrd_RES 0 RES 0 PWDN_ch1 0 Max EEPROM Burst size[1] 0 RES 0 DEVICE COUNT [1] Bit 1 0 ch2_RES_0 0 ch1_Slow 0 ch1_RES_1 0 ch1_BST_4 0 ch0_idle_thd_0 1 ch0_VOD_0 1 ch0_BST_0 0 ch0_RES_0 1 rx_delay_sel_0 0 Ovrd_RES 0 RES 0 PWDN_ch0 0 Max EEPROM Burst size[0] 0 RES 0 DEVICE COUNT [0] BIt 0 DS100KR401 15 www.ti.com www.ti.com 16 Value 0 ch6_Sel_mode Description 31 0 ch6_BST_6 30 Description Value 0 ch5_idle_tha_0 Value 1 Description 29 Value ch5_VOD_2 Description 28 1 ch5_BST_2 27 Description Value 0 ch5_Idle_sel Value 1 Description 26 Value ch4_DEM_1 Description 25 0 ch4_Sel_mode Value 0 Description 24 Value ch4_BST_6 Description 23 1 en_fast_idle_s 22 Description Value 0 ch3_idle_tha_1 Value 1 Description 21 Value ch3_RES_0 Description 20 1 ch3_BST_3 Value 0 Description 19 Value ch3_Idle_auto Description 18 0 ch2_DEM_2 17 Description Value 1 ch2_Sel_scp Value 0 16 ch2_BST_7 Description 15 Value Description 1 ch6_RES_2 1 ch6_BST_5 0 ch5_idle_thd_1 0 ch5_VOD_1 1 ch5_BST_1 0 ch5_RES_1 0 ch4_DEM_0 1 ch4_RES_2 1 ch4_BST_5 0 eqsd_mgain_n 0 ch3_idle_tha_0 1 ch3_VOD_2 1 ch3_BST_2 0 ch3_Idle_sel 1 ch2_DEM_1 0 ch2_Sel_mode 0 ch2_BST_6 0 ch6_RES_1 0 ch6_BST_4 0 ch5_idle_thd_0 1 ch5_VOD_0 1 ch5_BST_0 0 ch5_RES_0 0 ch4_Slow 0 ch4_RES_1 0 ch4_BST_4 0 eqsd_mgain_s 0 ch3_idle_thd_1 0 ch3_VOD_1 1 ch3_BST_1 0 ch3_RES_1 0 ch2_DEM_0 1 ch2_RES_2 1 ch2_BST_5 1 ch6_RES_0 1 ch6_BST_3 0 ch6_Idle_auto 0 ch5_DEM_2 1 ch5_Sel_scp 0 ch5_BST_7 0 ch4_idle_tha_1 1 ch4_RES_0 1 ch4_BST_3 0 ch4_Idle_auto 0 ch3_idle_thd_0 1 ch3_VOD_0 1 ch3_BST_0 0 ch3_RES_0 0 ch2_Slow 0 ch2_RES_1 0 ch2_BST_4 1 ch6_VOD_2 1 ch6_BST_2 0 ch6_Idle_sel 1 ch5_DEM_1 0 ch5_Sel_mode 0 ch5_BST_6 0 ch4_idle_tha_0 1 ch4_VOD_2 1 ch4_BST_2 0 ch4_Idle_sel 0 ovrd_fast_idle 0 ch3_DEM_2 1 ch3_Sel_scp 0 ch3_BST_7 0 ch2_idle_tha_1 1 ch2_RES_0 1 ch2_BST_3 0 ch3_DEM_0 1 ch3_RES_2 1 ch3_BST_5 0 ch2_idle_thd_1 0 ch2_VOD_1 1 ch2_BST_1 0 ch3_Slow 0 ch3_RES_1 0 ch3_BST_4 0 ch2_idle_thd_0 1 ch2_VOD_0 1 ch2_BST_0 0 ch6_VOD_1 1 ch6_BST_1 0 ch6_RES_1 0 ch5_DEM_0 1 ch5_RES_2 1 ch5_BST_5 0 ch4_idle_thd_1 0 ch4_VOD_1 1 ch4_BST_1 0 ch4_RXDET_1 0 1 ch6_VOD_0 1 ch6_BST_0 0 ch6_RES_0 0 ch5_Slow 0 ch5_RES_1 0 ch5_BST_4 0 ch4_idle_thd_0 1 ch4_VOD_0 1 ch4_BST_0 0 ch4_RXDET_0 0 0 ch6_DEM_2 1 ch6_Sel_scp 0 ch6_BST_7 0 ch5_idle_tha_1 1 ch5_RES_0 1 ch5_BST_3 0 ch5_Idle_auto 0 ch4_DEM_2 1 ch4_Sel_scp 0 ch4_BST_7 1 en_high_idle_th_n en_high_idle_th_s en_fast_idle_n 1 ch3_DEM_1 0 ch3_Sel_mode 0 ch3_BST_6 0 ch2_idle_tha_0 1 ch2_VOD_2 1 ch2_BST_2 DS100KR401 0 DEM__ovrd_S2 Value 0 Description 39 Value DEM_ovrd_N2 Description 38 0 ipp_dac_0 Value 0 Description 37 Value ch7_idle_tha_0 Description 36 1 ch7_VOD_2 35 Description Value 1 ch7_BST_2 Value 0 Description 34 Value ch7_Idle_sel 33 Description ch6_DEM_1 1 32 Value Description 1 DEM__ovrd_S1 1 DEM_ovrd_N1 0 RD23_67 0 ch7_idle_thd_1 0 ch7_VOD_1 1 ch7_BST_1 0 ch7_RES_1 0 ch6_DEM_0 0 DEM_ovrd_S0 0 DEM_ovrd_N0 0 RD01_45 0 ch7_idle_thd_0 1 ch7_VOD_0 1 ch7_BST_0 0 ch7_RES_0 0 ch6_Slow 1 VOD_ovrd_S2 1 VOD_ovrd_N2 0 RD_PD_ovrd 0 iph_dac_ns_1 0 ch7_DEM_2 1 ch7_Sel_scp 0 ch7_BST_7 0 ch6_idle_tha_1 0 VOD_ovrd_S1 0 VOD_ovrd_N1 0 RD_Sel_test 0 iph_dac_ns_0 1 ch7_DEM_1 0 ch7_Sel_mode 0 ch7_BST_6 0 ch6_idle_tha_0 1 VOD_ovrd_S0 1 VOD_ovrd_N0 0 RD_RESET_ovrd 0 ipp_dac_ns_1 0 ch7_DEM_0 1 ch7_RES_2 1 ch7_BST_5 0 ch6_idle_thd_1 0 SPARE0 0 SPARE0 0 PWDB_input_DC 0 ipp_dac_ns_0 0 ch7_Slow 0 ch7_RES_1 0 ch7_BST_4 0 ch6_idle_thd_0 0 SPARE1 0 SPARE1 0 DEM_VOD_ovrd 0 ipp_dac_1 0 ch7_idle_tha_1 1 ch7_RES_0 1 ch7_BST_3 0 ch7_Idle_auto DS100KR401 17 www.ti.com DS100KR401 TABLE 6. Example of EEPROM for 4 Devices Using 2 Address Maps 39 27 0x56 VOD CHA2 = 1.0V 40 28 0x00 DEM CHA2 = 0 (0dB) EEPROM Address EEPROM Comments Address (Hex) Data 41 29 0x00 EQ CHA3 = 00 42 2A 0x15 VOD CHA3 = 1.0V 0 43 2B 0x60 DEM CHA3 = 0 (0dB) 44 2C 0x00 45 2D 0x00 46 2E 0x54 47 2F 0x54 End Device 0, 1 - Address Offset 39 Begin Device 2, 3 Address Offset 3 00 0x43 CRC_EN = 0, Address Map = 1, >256 bytes = 0, Device Count[3:0] = 3 1 01 0x00 2 02 0x08 EEPROM Burst Size 3 03 0x00 CRC not used 4 04 0x0B Device 0 Address Location 48 30 0x00 5 05 0x00 CRC not used 49 31 0x00 6 06 0x0B Device 1 Address Location 50 32 0x04 51 33 0x07 52 34 0x00 53 35 0x00 EQ CHB0 = 00 54 36 0xAB VOD CHB0 = 1.0V 55 37 0x00 DEM CHB0 = 0 (0dB) 56 38 0x00 EQ CHB1 = 00 57 39 0x0A VOD CHB1 = 1.0V 58 3A 0xB0 DEM CHB1 = 0 (0dB) 3B 0x00 7 07 0x00 CRC not used 8 08 0x30 Device 2 Address Location 9 09 0x00 CRC not used 10 0A 0x30 Device 3 Address Location 11 0B 0x00 Begin Device 0, 1 Address Offset 3 12 0C 0x00 59 13 0D 0x04 60 3C 0x00 EQ CHB2 = 00 0x07 61 3D 0xAB VOD CHB2 = 1.0V 62 3E 0x00 DEM CHB2 = 0 (0dB) EQ CHB0 = 00 63 3F 0x00 EQ CHB3 = 00 VOD CHB0 = 1.0V 64 40 0x0A VOD CHB3 = 1.0V DEM CHB0 = 0 (0dB) 65 41 0xB0 DEM CHB3 = 0 (0dB) 42 0x01 14 0E 15 0F 0x00 16 10 0x00 17 18 11 12 0xAB 0x00 19 13 0x00 EQ CHB1 = 00 66 20 14 0x0A VOD CHB1 = 1.0V 67 43 0x80 DEM CHB1 = 0 (0dB) 68 44 0x01 EQ CHA0 = 00 69 45 0x56 VOD CHA0 = 1.0V EQ CHB2 = 00 70 46 0x00 DEM CHA0 = 0 (0dB) VOD CHB2 = 1.0V 71 47 0x00 EQ CHA1 = 00 48 0x15 VOD CHA1 = 1.0V DEM CHA1 = 0 (0dB) 21 15 0xB0 22 16 0x00 23 17 0x00 24 18 0xAB 25 19 0x00 DEM CHB2 = 0 (0dB) 72 26 1A 0x00 EQ CHB3 = 00 73 49 0x60 4A 0x00 27 1B 0x0A VOD CHB3 = 1.0V 74 28 1C 0xB0 DEM CHB3 = 0 (0dB) 75 4B 0x01 EQ CHA2 = 00 29 1D 0x01 76 4C 0x56 VOD CHA2 = 1.0V 0x80 77 4D 0x00 DEM CHA2 = 0 (0dB) 0x01 EQ CHA0 = 00 78 4E 0x00 EQ CHA3 = 00 4F 0x15 VOD CHA3 = 1.0V DEM CHA3 = 0 (0dB) 30 31 1E 1F 32 20 0x56 VOD CHA0 = 1.0V 79 33 21 0x00 DEM CHA0 = 0 (0dB) 80 50 0x60 51 0x00 34 22 0x00 EQ CHA1 = 00 81 35 23 0x15 VOD CHA1 = 1.0V 82 52 0x00 36 24 0x60 DEM CHA1 = 0 (0dB) 83 53 0x54 84 54 0x54 37 25 0x00 End Device 2, 3 - Address Offset 39 38 26 0x01 EQ CHA2 = 00 Note: CRC_EN = 0, Address Map = 1, >256 byte = 0, Device Count[3:0] = 3. This example has all 8–channels set to EQ = 00 (min boost), VOD = 1.0V, DEM = 0 (0dB) and multiple device can point to the same address map. www.ti.com 18 The System Management Bus interface is compatible to SMBus 2.0 physical layer specification. ENSMB = 1kΩ to VDD to enable SMBus slave mode and allow access to the configuration registers. The DS100KR401 has the AD[3:0] inputs in SMBus mode. These pins are the user set SMBUS slave address inputs. The AD[3:0] pins have internal pull-down. When left floating or pulled low the AD[3:0] = 0000'b, the device default address byte is B0'h. Based on the SMBus 2.0 specification, the DS100KR401 has a 7-bit slave address. The LSB is set to 0'b (for a WRITE). The device supports up to 16 address byte, which can be set with the AD[3:0] inputs. Below are the 16 addresses. SMBus TRANSACTIONS The device supports WRITE and READ transactions. See Register Description table for register address, type (Read/ Write, Read Only), default value and function information. WRITING A REGISTER To write a register, the following protocol is used (see SMBus 2.0 specification). 1. The Host drives a START condition, the 7-bit SMBus address, and a “0” indicating a WRITE. 2. The Device (Slave) drives the ACK bit (“0”). 3. The Host drives the 8-bit Register Address. 4. The Device drives an ACK bit (“0”). 5. The Host drive the 8-bit data byte. 6. The Device drives an ACK bit (“0”). 7. The Host drives a STOP condition. The WRITE transaction is completed, the bus goes IDLE and communication with other SMBus devices may now occur. TABLE 7. Device Slave Address Bytes AD[3:0] Settings Address Bytes (HEX) 0000 B0 0001 B2 0010 B4 0011 B6 0100 B8 0101 BA 0110 BC 0111 BE 1000 C0 1001 C2 1010 C4 1011 C6 1100 C8 1101 CA 1110 CC 1111 CE READING A REGISTER To read a register, the following protocol is used (see SMBus 2.0 specification). 1. The Host drives a START condition, the 7-bit SMBus address, and a “0” indicating a WRITE. 2. The Device (Slave) drives the ACK bit (“0”). 3. The Host drives the 8-bit Register Address. 4. The Device drives an ACK bit (“0”). 5. The Host drives a START condition. 6. The Host drives the 7-bit SMBus Address, and a “1” indicating a READ. 7. The Device drives an ACK bit “0”. 8. The Device drives the 8-bit data value (register contents). 9. The Host drives a NACK bit “1”indicating end of the READ transfer. 10. The Host drives a STOP condition. The READ transaction is completed, the bus goes IDLE and communication with other SMBus devices may now occur. Please see SMBus Register Map Table for more information. The SDA, SCL pins are 3.3V tolerant, but are not 5V tolerant. External pull-up resistor is required on the SDA. The resistor value can be from 1 kΩ to 5 kΩ depending on the voltage, loading and speed. The SCL may also require an external pull-up resistor and it depends on the Host that drives the bus. TRANSFER OF DATA VIA THE SMBus During normal operation the data on SDA must be stable during the time when SCL is High. There are three unique states for the SMBus: 19 www.ti.com DS100KR401 START: A High-to-Low transition on SDA while SCL is High indicates a message START condition. STOP: A Low-to-High transition on SDA while SCL is High indicates a message STOP condition. IDLE: If SCL and SDA are both High for a time exceeding tBUF from the last detected STOP condition or if they are High for a total exceeding the maximum specification for tHIGH then the bus will transfer to the IDLE state. System Management Bus (SMBus) and Configuration Registers DS100KR401 TABLE 8. SMBUS Slave Mode Register Map Address Register Name Bit (s) Field Type Default Description 0x00 7 Reserved R/W Set bit to 0. 6:3 Address Bit AD[3:0] R Observation of AD[3:0] bit [6]: AD3 [5]: AD2 [4]: AD1 [3]: AD0 2 EEPROM Read Done R 1: Device completed the read from external EEPROM. 1 Block Reset R/W 1: Block bit 0 from resettting the registers; self clearing. 0 Reset R/W SMBus Reset 1: Reset registers to default value; self clearing. Observation, Reset 0x00 0x01 PWDN Channels 7:0 PWDN CHx R/W 0x00 Power Down per Channel [7]: CH7 – CHA_3 [6]: CH6 – CHA_2 [5]: CH5 – CHA_1 [4]: CH4 – CHA_0 [3]: CH3 – CHB_3 [2]: CH2 – CHB_2 [1]: CH1 – CHB_1 [0]: CH0 – CHB_0 00'h = all channels enabled FF'h = all channels disabled Note: override RESET pin. 0x02 Override RESET, LPBK Control 7:6 Reserved R/W 0x00 Set bits to 0. 5:4 LPBK Control 00: Use LPBK pin control 01: INA to OUTB loopback 10: INB to OUTA loopback 11: Disable loopback and ignore LPBK pin. 3:1 Reserved Set bits to 0. 0 Override RESET 1: Block RESET pin control 0: Allow RESET pin control 0x05 Slave Mode CRC Bits 7:0 CRC bits R/W 0x00 CRC bits [7:0] 0x06 Slave CRC Control 7:5 Reserved R/W 0x10 Set bits to 0. 4 Reserved Set bit to 1. 3 Slave CRC 1: Disables the slave CRC mode 0: Enables the slave CRC mode Note: In order to change VOD, DEM and EQ of the channels in slave mode, set bit to 1 to disable the CRC. 2:0 Reserved 7 Reserved 6 Override SD_TH 1: Block SD_TH pin control 0: Allow SD_TH pin control 5:2 Reserved Set bits to 0. 1 Override DEM 1: Block DEM pin control 0: Allow DEM pin control 0 Reserved Set bit to 0. 7:0 Reserved 0x08 0x0E www.ti.com Override Pin Control CH0 - CHB0 Reserved Set bits to 0. R/W R/W 20 0x00 0x00 Set bit to 0. Set bits to 0. CH0 - CHB0 EQ 7:0 EQ Control R/W 0x2F IB0 EQ Control - total of 256 levels. See Table 2. 0x10 CH0 - CHB0 VOD 7 Short Circuit Protection R/W 0xAD 1: Enable the short circuit protection 0: Disable the short circuit protection 6 Reserved Set bit to 0. 5:3 Reserved Set bits to default value - 101. 2:0 VOD Control OB0 VOD Control 000: 0.7 V 001: 0.8 V 010: 0.9 V 011: 1.0 V 100: 1.1 V 101: 1.2 V (default) 110: 1.3 V 111: 1.4 V 7 STATUS R 6:5 STATUS R Observation bit for CH0 - CHB0. 4:3 Reserved R/W Set bits to 0. 2:0 DEM Control R/W OB0 DEM Control 000: 0 dB 001: –1.5 dB 010: –3.5 dB (default) 011: –5 dB 100: –6 dB 101: –8 dB 110: –9 dB 111: –12 dB 7:4 Reserved R/W 3:2 IDLE thd De-assert threshold 00 = 110 mVp-p (default) 01 = 100 mVp-p 10 = 150 mVp-p 11 = 130 mVp-p Note: override the SD_TH pin. 1:0 IDLE tha Assert threshold 00 = 180 mVp-p (default) 01 = 160 mVp-p 10 = 210 mVp-p 11 = 190 mVp-p Note: override the SD_TH pin. 0x11 0x12 CH0 - CHB0 DEM CH0 - CHB0 IDLE Threshold 0x02 0x00 Observation bit for CH0 - CHB0. Set bits to 0. 0x15 CH1 - CHB1 Reserved 7:0 Reserved R/W 0x00 Set bits to 0. 0x16 CH1 - CHB1 EQ 7:0 EQ Control R/W 0x2F IB1 EQ Control - total of 256 levels. See Table 2. 21 DS100KR401 0x0F www.ti.com DS100KR401 0x17 0x18 0x19 CH1 - CHB1 VOD CH1 - CHB1 DEM CH1 - CHB1 IDLE Threshold R/W 0xAD 7 Short Circuit Protection 6 Reserved Set bit to 0. 5:3 Reserved Set bits to default value - 101. 2:0 VOD Control OB1 VOD Control 000: 0.7 V 001: 0.8 V 010: 0.9 V 011: 1.0 V 100: 1.1 V 101: 1.2 V (default) 110: 1.3 V 111: 1.4 V 7 STATUS R 6:5 STATUS R Observation bit for CH1 - CHB1. 4:3 Reserved R/W Set bits to 0. 2:0 DEM Control R/W OB1 DEM Control 000: 0 dB 001: –1.5 dB 010: –3.5 dB (default) 011: –5 dB 100: –6 dB 101: –8 dB 110: –9 dB 111: –12 dB 7:4 Reserved R/W 3:2 IDLE thd De-assert threshold 00 = 110 mVp-p (default) 01 = 100 mVp-p 10 = 150 mVp-p 11 = 130 mVp-p Note: override the SD_TH pin. 1:0 IDLE tha Assert threshold 00 = 180 mVp-p (default) 01 = 160 mVp-p 10 = 210 mVp-p 11 = 190 mVp-p Note: override the SD_TH pin. 0x02 0x00 1: Enable the short circuit protection 0: Disable the short circuit protection Observation bit for CH1 - CHB1. Set bits to 0. 0x1C CH2 - CHB2 Reserved 7:0 Reserved R/W 0x00 Set bits to 0. 0x1D CH2 - CHB2 EQ 7:0 EQ Control R/W 0x2F IB2 EQ Control - total of 256 levels. See Table 2. 0x1E CH2 - CHB2 VOD 7 Short Circuit Protection R/W 0xAD 1: Enable the short circuit protection 0: Disable the short circuit protection 6 Reserved Set bit to 0. 5:3 Reserved Set bits to default value - 101. 2:0 VOD Control OB2 VOD Control 000: 0.7 V 001: 0.8 V 010: 0.9 V 011: 1.0 V 100: 1.1 V 101: 1.2 V (default) 110: 1.3 V 111: 1.4 V www.ti.com 22 0x20 CH2 - CHB2 DEM CH2 - CHB2 IDLE Threshold 0x02 7 STATUS R 6:5 STATUS R Observation bit for CH2 - CHB2. 4:3 Reserved R/W Set bits to 0. 2:0 DEM Control R/W OB2 DEM Control 000: 0 dB 001: –1.5 dB 010: –3.5 dB (default) 011: –5 dB 100: –6 dB 101: –8 dB 110: –9 dB 111: –12 dB 7:4 Reserved R/W 3:2 IDLE thd De-assert threshold 00 = 110 mVp-p (default) 01 = 100 mVp-p 10 = 150 mVp-p 11 = 130 mVp-p Note: override the SD_TH pin. 1:0 IDLE tha Assert threshold 00 = 180 mVp-p (default) 01 = 160 mVp-p 10 = 210 mVp-p 11 = 190 mVp-p Note: override the SD_TH pin. 0x00 Observation bit for CH2 - CHB2. Set bits to 0. 0x23 CH3 - CHB3 Reserved 7:0 Reserved R/W 0x00 Set bits to 0. 0x24 CH3 - CHB3 EQ 7:0 EQ Control R/W 0x2F IB3 EQ Control - total of 256 levels. See Table 2. 0x25 CH3 - CHB3 VOD 7 Short Circuit Protection R/W 0xAD 1: Enable the short circuit protection 0: Disable the short circuit protection 6 Reserved Set bit to 0. 5:3 Reserved Set bits to default value - 101. 2:0 VOD Control OB0 VOD Control 000: 0.7 V 001: 0.8 V 010: 0.9 V 011: 1.0 V 100: 1.1 V 101: 1.2 V (default) 110: 1.3 V 111: 1.4 V 7 STATUS R 6:5 STATUS R Observation bit for CH3 - CHB3. 4:3 Reserved R/W Set bits to 0. 2:0 DEM Control R/W OB3 DEM Control 000: 0 dB 001: –1.5 dB 010: –3.5 dB (default) 011: –5 dB 100: –6 dB 101: –8 dB 110: –9 dB 111: –12 dB 0x26 CH3 - CHB3 DEM 23 0x02 DS100KR401 0x1F Observation bit for CH3 - CHB3. www.ti.com DS100KR401 0x27 CH3 - CHB3 IDLE Threshold R/W 0x00 7:4 Reserved Set bits to 0. 3:2 IDLE thd De-assert threshold 00 = 110 mVp-p (default) 01 = 100 mVp-p 10 = 150 mVp-p 11 = 130 mVp-p Note: override the SD_TH pin. 1:0 IDLE tha Assert threshold 00 = 180 mVp-p (default) 01 = 160 mVp-p 10 = 210 mVp-p 11 = 190 mVp-p Note: override the SD_TH pin. 0x2B CH4 - CHA0 Reserved 7:0 Reserved R/W 0x00 Set bits to 0. 0x2C CH4 - CHA0 EQ 7:0 EQ Control R/W 0x2F IA0 EQ Control - total of 256 levels. See Table 2. 0x2D CH4 - CHA0 VOD 7 Short Circuit Protection R/W 0xAD 1: Enable the short circuit protection 0: Disable the short circuit protection 6 Reserved Set bit to 0. 5:3 Reserved Set bits to default value - 101. 2:0 VOD Control OA0 VOD Control 000: 0.7 V 001: 0.8 V 010: 0.9 V 011: 1.0 V 100: 1.1 V 101: 1.2 V (default) 110: 1.3 V 111: 1.4 V 7 STATUS R 6:5 STATUS R Observation bit for CH4 - CHA0. 4:3 Reserved R/W Set bits to 0. 2:0 DEM Control R/W OA0 DEM Control 000: 0 dB 001: –1.5 dB 010: –3.5 dB (default) 011: –5 dB 100: –6 dB 101: –8 dB 110: –9 dB 111: –12 dB 7:4 Reserved R/W 3:2 IDLE thd De-assert threshold 00 = 110 mVp-p (default) 01 = 100 mVp-p 10 = 150 mVp-p 11 = 130 mVp-p Note: override the SD_TH pin. 1:0 IDLE tha Assert threshold 00 = 180 mVp-p (default) 01 = 160 mVp-p 10 = 210 mVp-p 11 = 190 mVp-p Note: override the SD_TH pin. 0x2E 0x2F www.ti.com CH4 - CHA0 DEM CH4 - CHA0 IDLE Threshold 24 0x02 0x00 Observation bit for CH4 - CHA0. Set bits to 0. CH5 - CHA1 Reserved 7:0 Reserved R/W 0x00 Set bits to 0. 0x33 CH5 - CHA1 EQ 7:0 EQ Control R/W 0x2F IA1 EQ Control - total of 256 levels. See Table 2. 0x34 CH5 - CHA1 VOD 7 Short Circuit Protection R/W 0xAD 1: Enable the short circuit protection 0: Disable the short circuit protection 6 Reserved Set bit to 0. 5:3 Reserved Set bits to default value - 101. 2:0 VOD Control OA1 VOD Control 000: 0.7 V 001: 0.8 V 010: 0.9 V 011: 1.0 V 100: 1.1 V 101: 1.2 V (default) 110: 1.3 V 111: 1.4 V 7 STATUS R 6:5 STATUS R Observation bit for CH5 - CHA1. 4:3 Reserved R/W Set bits to 0. 2:0 DEM Control R/W OA1 DEM Control 000: 0 dB 001: –1.5 dB 010: –3.5 dB (default) 011: –5 dB 100: –6 dB 101: –8 dB 110: –9 dB 111: –12 dB 7:4 Reserved R/W 3:2 IDLE thd De-assert threshold 00 = 110 mVp-p (default) 01 = 100 mVp-p 10 = 150 mVp-p 11 = 130 mVp-p Note: override the SD_TH pin. 1:0 IDLE tha Assert threshold 00 = 180 mVp-p (default) 01 = 160 mVp-p 10 = 210 mVp-p 11 = 190 mVp-p Note: override the SD_TH pin. 0x35 0x36 CH5 - CHA1 DEM CH5 - CHA1 IDLE Threshold 0x02 0x00 Observation bit for CH5 - CHA1. Set bits to 0. 0x39 CH6 - CHA2 Reserved 7:0 Reserved R/W 0x00 Set bits to 0. 0x3A CH6 - CHA2 EQ 7:0 EQ Control R/W 0x2F IA2 EQ Control - total of 256 levels. See Table 2. 25 DS100KR401 0x32 www.ti.com DS100KR401 0x3B 0x3C 0x3D CH6 - CHA2 VOD CH6 - CHA2 DEM CH6 - CHA2 IDLE Threshold R/W 0xAD 7 Short Circuit Protection 6 Reserved Set bit to 0. 5:3 Reserved Set bits to default value - 101. 2:0 VOD Control OA2 VOD Control 000: 0.7 V 001: 0.8 V 010: 0.9 V 011: 1.0 V 100: 1.1 V 101: 1.2 V (default) 110: 1.3 V 111: 1.4 V 7 STATUS R 6:5 STATUS R Observation bit for CH6 - CHA2. 4:3 Reserved R/W Set bits to 0. 2:0 DEM Control R/W OA2 DEM Control 000: 0 dB 001: –1.5 dB 010: –3.5 dB (default) 011: –5 dB 100: –6 dB 101: –8 dB 110: –9 dB 111: –12 dB 7:4 Reserved R/W 3:2 IDLE thd De-assert threshold 00 = 110 mVp-p (default) 01 = 100 mVp-p 10 = 150 mVp-p 11 = 130 mVp-p Note: override the SD_TH pin. 1:0 IDLE tha Assert threshold 00 = 180 mVp-p (default) 01 = 160 mVp-p 10 = 210 mVp-p 11 = 190 mVp-p Note: override the SD_TH pin. 0x02 0x00 1: Enable the short circuit protection 0: Disable the short circuit protection Observation bit for CH6 - CHA2. Set bits to 0. 0x40 CH7 - CHA3 Reserved 7:0 Reserved R/W 0x00 Set bits to 0. 0x41 CH7 - CHA3 EQ 7:0 EQ Control R/W 0x2F IA3 EQ Control - total of 256 levels. See Table 2. 0x42 CH7 - CHA3 VOD 7 Short Circuit Protection R/W 0xAD 1: Enable the short circuit protection 0: Disable the short circuit protection 6 Reserved Set bit to 0. 5:3 Reserved Set bits to default value - 101. 2:0 VOD Control OA3 VOD Control 000: 0.7 V 001: 0.8 V 010: 0.9 V 011: 1.0 V 100: 1.1 V 101: 1.2 V (default) 110: 1.3 V 111: 1.4 V www.ti.com 26 0x44 0x51 CH7 - CHA3 DEM CH7 - CHA3 IDLE Threshold Device ID 0x02 7 STATUS R 6:5 STATUS R Observation bit for CH7 - CHA3. 4:3 Reserved R/W Set bits to 0. 2:0 DEM Control R/W OA3 DEM Control 000: 0 dB 001: –1.5 dB 010: –3.5 dB (default) 011: –5 dB 100: –6 dB 101: –8 dB 110: –9 dB 111: –12 dB 7:4 Reserved R/W 3:2 IDLE thd De-assert threshold 00 = 110 mVp-p (default) 01 = 100 mVp-p 10 = 150 mVp-p 11 = 130 mVp-p Note: override the SD_TH pin. 1:0 IDLE tha Assert threshold 00 = 180 mVp-p (default) 01 = 160 mVp-p 10 = 210 mVp-p 11 = 190 mVp-p Note: override the SD_TH pin. 7:5 VERSION 4:0 ID R 0x00 0x44 DS100KR401 0x43 Observation bit for CH7 - CHA3. Set bits to 0. 010'b 00100'b 27 www.ti.com DS100KR401 - 100Ω. It is preferable to route differential lines exclusively on one layer of the board, particularly for the input traces. The use of vias should be avoided if possible. If vias must be used, they should be used sparingly and must be placed symmetrically for each side of a given differential pair. Whenever differential vias are used the layout must also provide for a low inductance path for the return currents as well. Route the differential signals away from other signals and noise sources on the printed circuit board. See AN-1187 for additional information on LLP packages. Applications Information GENERAL RECOMMENDATIONS The DS100KR401 is a high performance circuit capable of delivering excellent performance. Careful attention must be paid to the details associated with high-speed design as well as providing a clean power supply. Refer to the information below and Revision 4 of the LVDS Owner's Manual for more detailed information on high speed design tips to address signal integrity design issues. PCB LAYOUT CONSIDERATIONS FOR DIFFERENTIAL PAIRS The CML inputs and outputs have been optimized to work with interconnects using a controlled differential impedance of 85 30147910 FIGURE 5. Typical Routing Options The graphic shown above depicts different transmission line topologies which can be used in various combinations to achieve the optimal system performance. Impedance discontinuities at the differential via can be minimized or eliminated by increasing the swell around each hole and providing for a www.ti.com low inductance return current path. When the via structure is associated with thick backplane PCB, further optimization such as back drilling is often used to reduce the deterimential high frequency effects of stubs on the signal path. 28 29 www.ti.com DS100KR401 use of bypass capacitors is required. A 0.1 μF bypass capacitor should be connected to each VDD pin such that the capacitor is placed as close as possible to the DS100KR401. Smaller body size capacitors can help facilitate proper component placement. In the case of 3.3V mode operation with the internal LDO regulator, recommend using capacitors with capacitance in the range of 1.0 μF to 10 μF should be incorporated in the power supply bypassing design for the VIN pin. These capacitors should be ultra-low ESR ceramic. POWER SUPPLY BYPASSING Two approaches are recommended to ensure that the DS100KR401 is provided with an adequate power supply. First, the supply (VDD) and ground (GND) pins should be connected to power planes routed on adjacent layers of the printed circuit board. The layer thickness of the dielectric should be minimized so that the VDD and GND planes create a low inductance supply with distributed capacitance. Second, careful attention to supply bypassing through the proper DS100KR401 Typical Performance Curves Characteristics 30147927 FIGURE 6. Power Dissipation (PD) vs. Output Differential Voltage (VOD) 30147928 FIGURE 7. Output Differential Voltage (VOD = 1.0 Vp-p) vs. Supply Voltage (VDD) 30147929 FIGURE 8. Output Differential Voltage (VOD = 1.0 Vp-p) vs. Temperature www.ti.com 30 DS100KR401 Typical Performance Eye Diagrams Characteristics 30147930 FIGURE 9. Test Setup Connections Diagram 30147931 FIGURE 10. TL = 20 inch 4–mil FR4 trace, DS100KR401 settings: EQ[1:0] = R, R = 15'h, DEM[1:0] = float, float 30147932 FIGURE 11. TL = 30 inch 4–mil FR4 trace, DS100KR401 settings: EQ[1:0] = float, R = 1F'h, DEM[1:0] = float, float 31 www.ti.com DS100KR401 30147933 FIGURE 12. Test Setup Connections Diagram 30147934 FIGURE 13. TL1 = 20 inch 4–mil FR4 trace, TL2 = 15 inch 4–mil FR4 trace, DS100KR401 settings: EQ[1:0] = R, R = 15'h, DEM[1:0] = float, float 30147935 FIGURE 14. TL1 = 30 inch 4–mil FR4 trace, TL2 = 15 inch 4–mil FR4 trace, DS100KR401 settings: EQ[1:0] = float, R = 1F'h, DEM[1:0] = float, float www.ti.com 32 DS100KR401 Physical Dimensions inches (millimeters) unless otherwise noted Order Number DS100KR401SQ (Tape and Reel 2,000 units) Order Number DS100KR401SQE (Tape and Reel 250 units) Package Number SQA54A (See AN-1187 for PCB Design and Assembly Recommendations) 33 www.ti.com DS100KR401 Ultra Low Power, 4 Lane (8-channel, bi-directional) Repeater for Data-rates up to 10.3 Gbps Notes www.ti.com IMPORTANT NOTICE Texas Instruments Incorporated and its subsidiaries (TI) reserve the right to make corrections, modifications, enhancements, improvements, and other changes to its products and services at any time and to discontinue any product or service without notice. Customers should obtain the latest relevant information before placing orders and should verify that such information is current and complete. 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