ZHCSCZ2A July   2014  – September 2014 DS125BR820

PRODUCTION DATA.  

  1. 特性
  2. 应用
  3. 说明
  4. 修订历史记录
  5. Pin Configuration and Functions
  6. Specifications
    1. 6.1 Absolute Maximum Ratings
    2. 6.2 Handling Ratings
    3. 6.3 Recommended Operating Conditions
    4. 6.4 Thermal Information
    5. 6.5 Electrical Characteristics
    6. 6.6 Electrical Characteristics — Serial Management Bus Interface
    7. 6.7 Timing Requirements Serial Bus Interface
    8. 6.8 Typical Characteristics
  7. Detailed Description
    1. 7.1 Overview
    2. 7.2 Functional Block Diagram
      1. 7.2.1 Functional Datapath Blocks
    3. 7.3 Feature Description
    4. 7.4 Device Functional Modes
      1. 7.4.1 Pin Control Mode:
      2. 7.4.2 Slave SMBus Mode:
      3. 7.4.3 SMBus Master Mode
    5. 7.5 Signal Conditioning Settings
    6. 7.6 Programming
      1. 7.6.1 EEPROM Register Map for Single Device
    7. 7.7 Register Maps
      1. 7.7.1 Transfer Of Data Via The SMBus
      2. 7.7.2 SMBus Transactions
      3. 7.7.3 Writing a Register
      4. 7.7.4 Reading a Register
      5. 7.7.5 Detailed Register Map
  8. Applications and Implementation
    1. 8.1 Application Information
      1. 8.1.1 Signal Integrity in 40G-CR4/KR4/SAS/SATA/PCIe Applications
      2. 8.1.2 Signal Integrity in 40G-SR4/LR4 Applications
      3. 8.1.3 Rx Detect Functionality in 40G-CR4/KR4/SAS/SATA Applications
    2. 8.2 Typical Applications
      1. 8.2.1 Generic High Speed Repeater
        1. 8.2.1.1 Design Requirements
        2. 8.2.1.2 Detailed Design Procedure
        3. 8.2.1.3 Application Performance Plots
      2. 8.2.2 Front Port Applications (40G-CR4/SR4/LR4)
        1. 8.2.2.1 Design Requirements
        2. 8.2.2.2 Detailed Design Procedure
        3. 8.2.2.3 Application Performance Plots
      3. 8.2.3 PCIe Board Applications (PCIe Gen-3)
        1. 8.2.3.1 Design Requirements
        2. 8.2.3.2 Design Procedure
        3. 8.2.3.3 Application Performance Plots
  9. Power Supply Recommendations
  10. 10Layout
    1. 10.1 Layout Guidelines
    2. 10.2 Layout Example
  11. 11器件和文档支持
    1. 11.1 商标
    2. 11.2 静电放电警告
    3. 11.3 术语表
  12. 12机械封装和可订购信息

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机械数据 (封装 | 引脚)
散热焊盘机械数据 (封装 | 引脚)
订购信息

8 Applications and Implementation

NOTE

Information in the following applications sections is not part of the TI component specification, and TI does not warrant its accuracy or completeness. TI’s customers are responsible for determining suitability of components for their purposes. Customers should validate and test their design implementation to confirm system functionality.

8.1 Application Information

8.1.1 Signal Integrity in 40G-CR4/KR4/SAS/SATA/PCIe Applications

In 40G-CR4/KR4/SAS/SATA/PCIe applications, specifications require Rx-Tx link training to establish and optimize signal conditioning settings for data rates up to 12.5 Gbps. In link training, the Rx partner requests a series of FIR coefficients from the Tx partner at speed. This polling sequence is designed to pre-condition the signal path with an optimized link between the endpoints. Link training occurs at the following data-rates:

Table 10. Link Training Data-Rates

Protocol(1) Operating Data Rate (Gbps)
40G-CR4 10.3125
40G-KR4 10.3125
SAS-3 12.0
PCIe Gen-3 8.0
(1) There is no link training with Tx FIR coefficients for the respective lower generation data rates.

The DS125BR820 works to extend the reach possible by using active linear equalization to the channel, boosting attenuated signals so that they can be more easily recovered at the Rx. The repeater outputs are specially designed to be transparent to Tx FIR signaling in order to pass information critical for optimal link training to the Rx. Suggested settings for the A-channels and B-channels are given in Table 11 and Table 12. Further adjustments to EQx and VODx settings may optimize signal margin on the link for different system applications:

Table 11. Suggested Device Settings in Pin Mode

Channel Settings Pin Mode
EQx Level 1
VODx[1:0] Level 6 (1, 0)

Table 12. Suggested Device Settings in SMBus Modes

Channel Settings SMBus Modes
EQx 0x00
VODx 110'b
VOD_DB 000'b

The SMBus Slave Mode code example in Table 13 may be used to program the DS125BR820 with the recommended device settings.

Table 13. SMBus Example Sequence

Register Write Value Comments
0x06 0x18 Set SMBus Slave Mode Register Enable.
0x0F 0x00 Set CHB_0 EQ to 0x00.
0x10 0xAE Set CHB_0 VOD to 110'b.
0x11 0x00 Set CHB_0 VOD_DB to 000'b.
0x16 0x00 Set CHB_1 EQ to 0x00.
0x17 0xAE Set CHB_1 VOD to 110'b.
0x18 0x00 Set CHB_1 VOD_DB to 000'b.
0x1D 0x00 Set CHB_2 EQ to 0x00.
0x1E 0xAE Set CHB_2 VOD to 110'b.
0x1F 0x00 Set CHB_2 VOD_DB to 000'b.
0x24 0x00 Set CHB_3 EQ to 0x00.
0x25 0xAE Set CHB_3 VOD to 110'b.
0x26 0x00 Set CHB_3 VOD_DB to 000'b.
0x2C 0x00 Set CHA_0 EQ to 0x00.
0x2D 0xAE Set CHA_0 VOD to 110'b.
0x2E 0x00 Set CHA_0 VOD_DB to 000'b.
0x33 0x00 Set CHA_1 EQ to 0x00.
0x34 0xAE Set CHA_1 VOD to 110'b.
0x35 0x00 Set CHA_1 VOD_DB to 000'b.
0x3A 0x00 Set CHA_2 EQ to 0x00.
0x3B 0xAE Set CHA_2 VOD to 110'b.
0x3C 0x00 Set CHA_2 VOD_DB to 000'b.
0x41 0x00 Set CHA_3 EQ to 0x00.
0x42 0xAE Set CHA_3 VOD to 110'b.
0x43 0x00 Set CHA_3 VOD_DB to 000'b.

8.1.2 Signal Integrity in 40G-SR4/LR4 Applications

In 40G-SR4/LR4 applications, the ideal device settings must be tuned. In particular, EQ and VOD settings must be optimized in order to aid the link partners in meeting the nPPI eye mask test. While tuning the DS125BR820 contributes to signal quality improvement, it is equally important to ensure that the link partner ASIC Tx FIR signal characteristics are optimized as well to facilitate error-free data transmission. Suggested settings for the A-channels and B-channels in a 40G-SR4/LR4 environment can be referenced in Table 11 and Table 12.

8.1.3 Rx Detect Functionality in 40G-CR4/KR4/SAS/SATA Applications

Unlike PCIe systems, 40G-CR4/KR4/SAS/SATA systems use a low speed communications sequence to detect and communicate device capabilities between host ASIC and link partners. This communication eliminates the need to detect for endpoints like in a PCIe application. For 40G-CR4/KR4/SAS/SATA systems, it is recommended to tie the RXDET pin high. This ensures any link-training sequences sent by the host ASIC can reach the link partner receiver without any additional latency due to termination detection sequences.

8.2 Typical Applications

8.2.1 Generic High Speed Repeater

The DS125BR820 extends PCB and cable reach in multiple applications by using active linear equalization. The high linearity of this device aids specifically in protocols requiring link training and can be used in line cards, backplanes, motherboards, and active cable assemblies, thereby improving margin and overall eye performance. The capability of the repeater can be explored across a range of data rates and ASIC-to-link-partner signaling, as shown in the following two test setup connections.

30198730.gifFigure 9. Test Setup Connections Diagram
30198733.gifFigure 10. Test Setup Connections Diagram

8.2.1.1 Design Requirements

As with any high speed design, there are many factors which influence the overall performance. Below are a list of critical areas for consideration and study during design.

  • Use 100 Ω impedance traces. Generally these are very loosely coupled to ease routing length differences.
  • Place AC-coupling capacitors near to the receiver end of each channel segment to minimize reflections.
  • The maximum body size for AC-coupling capacitors is 0402.
  • Back-drill connector vias and signal vias to minimize stub length.
  • Use Reference plane vias to ensure a low inductance path for the return current.

8.2.1.2 Detailed Design Procedure

The DS125BR820 is designed to be placed at an offset location with respect to the overall channel attenuation.In order to optimize performance, the repeater requires tuning to extend the reach of the cable or trace length while also recovering a solid eye opening. To tune the repeater, the settings mentioned in Table 11 (for Pin Mode) and Table 12 (for SMBus Modes) are recommended as a default starting point for most applications. Once these settings are configured, additional tuning of the EQ and, to a lesser extent, VOD may be required to optimize the repeater performance for each specific application environment.

Examples of the repeater performance as a generic high speed datapath repeater are illustrated in the performance curves in the next section.

8.2.1.3 Application Performance Plots

8G_5in5mil_BR820_scope_NR_eye.gif
No Repeater Used
TJ (1.0E-12) = 21.6 ps
Figure 11. TL = 5 Inch 5–Mil FR4 Trace,
No Repeater, 8 Gbps
8G_10in5mil_BR820_scope_NR_eye.gif
No Repeater Used
TJ (1.0E-12) = 43.7 ps
Figure 13. TL = 10 Inch 5–Mil FR4 Trace,
No Repeater, 8 Gbps
8G_20in5mil_BR820_scope_NR_eye.gif
No Repeater Used
TJ (1.0E-12) = Not Available Due to Closed Eye
Figure 15. TL = 20 Inch 5–Mil FR4 Trace,
No Repeater, 8 Gbps
8G_5m30AWG_BR820_scope_NR_eye.gif
No Repeater
TJ (1.0E-12) = Not Available Due to Closed Eye
Figure 17. TL = 5-Meter 30-AWG 100 Ω Twin-Axial Cable,
No Repeater, 8 Gbps
10.3125G_5in5mil_BR820_scope_NR_eye.gif
A. No Repeater Used
TJ (1.0E-12) = 24.3 ps
Figure 19. TL = 5 Inch 5–Mil FR4 Trace,
No Repeater, 10.3125 Gbps
10.3125G_10in5mil_BR820_scope_NR_eye.gif
A. No Repeater Used
TJ (1.0E-12) = 50.6 ps
Figure 21. TL = 10 Inch 5–Mil FR4 Trace,
No Repeater, 10.3125 Gbps
10.3125G_20in5mil_BR820_scope_NR_eye.gif
A. No Repeater Used
TJ (1.0E-12) = Not Available Due to Closed Eye
Figure 23. TL = 20 Inch 5–Mil FR4 Trace,
No Repeater, 10.3125 Gbps
12G_5in5mil_BR820_scope_NR_eye.gif
A. No Repeater
TJ (1.0E-12) = 26.1 ps
Figure 25. TL = 5 Inch 5–Mil FR4 Trace,
No Repeater, 12 Gbps
12G_10in5mil_BR820_scope_NR_eye.gif
A. No Repeater
TJ (1.0E-12) = 56.6 ps
Figure 27. TL = 10 Inch 5–Mil FR4 Trace,
No Repeater, 12 Gbps
8G_15in5milRX_10in5milTX_BR820_scope_NR_eye.gif
No Repeater Used
TJ (1.0E-12) = Not Available Due to Closed Eye
Figure 29. TL1 = 15 Inch 5–Mil FR4 Trace,
TL2 = 10 Inch 5–Mil FR4 Trace,
No Repeater, 8 Gbps
10.3125G_15in5milRX_10in5milTX_BR820_scope_NR_eye.gif
A. No Repeater Used
TJ (1.0E-12) = Not Available Due to Closed Eye
Figure 31. TL1 = 15 Inch 5–Mil FR4 Trace,
TL2 = 10 Inch 5–Mil FR4 Trace,
No Repeater, 10.3125 Gbps
8G_5in5mil_BR820_scope_EQ1_eye.gif
DS125BR820 Settings: EQA = Level 2, VODA = Level 6
TJ (1.0E-12) = 13.6 ps
Figure 12. TL = 5 Inch 5–Mil FR4 Trace,
DS125BR820 CHA_0, 8 Gbps
8G_10in5mil_BR820_scope_EQ2_eye.gif
DS125BR820 Settings: EQA = Level 3, VODA = Level 6
TJ (1.0E-12) = 18.1 ps
Figure 14. TL= 10 Inch 5–Mil FR4 Trace,
DS125BR820 CHA_0, 8 Gbps
8G_20in5mil_BR820_scope_EQ3_eye.gif
DS125BR820 Settings: EQA = Level 4, VODA = Level 6
TJ (1.0E-12) = 35.5 ps
Figure 16. TL = 20 Inch 5–Mil FR4 Trace,
DS125BR820 CHA_0, 8 Gbps
8G_5m30AWG_BR820_scope_EQ3_eye.gif
DS125BR820 Settings: EQA = Level 4, VODA = Level 6
TJ (1.0E-12) = 41.4 ps
Figure 18. TL = 5-Meter 30-AWG 100 Ω Twin-Axial Cable,
DS125BR820 CHA_0, 8 Gbps
10.3125G_5in5mil_BR820_scope_EQ1_eye.gif
A. DS125BR820 Settings: EQA = Level 2, VODA = Level 6
TJ (1.0E-12) = 14.0 ps
Figure 20. TL = 5 Inch 5–Mil FR4 Trace,
DS125BR820 CHA_0, 10.3125 Gbps
10.3125G_10in5mil_BR820_scope_EQ2_eye.gif
A. DS125BR820 Settings: EQA = Level 3, VODA = Level 6
TJ (1.0E-12) = 18.7 ps
Figure 22. TL= 10 Inch 5–Mil FR4 Trace,
DS125BR820 CHA_0, 10.3125 Gbps
10.3125G_20in5mil_BR820_scope_EQ3_eye.gif
A. DS125BR820 Settings: EQA = Level 4, VODA = Level 6
TJ (1.0E-12) = 49.1 ps
Figure 24. TL = 20 Inch 5–Mil FR4 Trace,
DS125BR820 CHA_0, 10.3125 Gbps
12G_5in5mil_BR820_scope_EQ1_eye.gif
A. DS125BR820 Settings: EQA = Level 2, VODA = Level 6
TJ (1.0E-12) = 13.1 ps
Figure 26. TL = 5 Inch 5–Mil FR4 Trace,
DS125BR820 CHA_0, 12 Gbps
12G_10in5mil_BR820_scope_EQ2_eye.gif
A. DS125BR820 Settings: EQA = Level 3, VODA = Level 6
TJ (1.0E-12) = 20.1 ps
Figure 28. TL = 10 Inch 5–Mil FR4 Trace,
DS125BR820 CHA_0, 12 Gbps
8G_15in5milRX_10in5milTX_BR820_scope_EQ3_eye.gif
DS125BR820 Settings: EQA = Level 4, VODA = Level 6
TJ (1.0E-12) = 33.0 ps
Figure 30. TL1 = 15 Inch 5–Mil FR4 Trace,
TL2 = 10 Inch 5–Mil FR4 Trace,
DS125BR820 CHA_0, 8 Gbps
10.3125G_15in5milRX_10in5milTX_BR820_scope_EQ3_eye.gif
A. DS125BR820 Settings: EQA = Level 4, VODA = Level 6
TJ (1.0E-12) = 47.9 ps
Figure 32. TL1 = 15 Inch 5–Mil FR4 Trace,
TL2 = 10 Inch 5–Mil FR4 Trace,
DS125BR820 CHA_0, 10.3125 Gbps

8.2.2 Front Port Applications (40G-CR4/SR4/LR4)

The DS125BR820 can be used in front port applications to extend the reach between the host ASIC and the front-port cage. Front port applications typically include 40G-CR4/SR4/LR4. For 40GbE front port optical protocols like 40G-SR4/LR4, the DS125BR820 is designed to support the front-port eye mask and jitter requirements of applicable standards like nPPI. For 40GbE front port copper protocols like 40G-CR4, the DS125BR820 is designed to provide channel equalization in a transparent fashion so as not to inhibit IEEE802.3ba Clause 72 link training. In all of these front port cases, the DS125BR820 can also be used to support eye mask and jitter requirements for SFF-8431 if the 40GbE QSFP+ port is intended to support 4x10G SFP+ applications as well. Below is a typical example of the DS125BR820 used in a front port line-card application.

app_diagram.gifFigure 33. Typical Front-Port System Configuration

8.2.2.1 Design Requirements

As with any high speed design, there are many factors that influence the overall performance. Please reference Design Requirements in the Generic High Speed Repeater application section for a list of critical areas for consideration and study during design.

8.2.2.2 Detailed Design Procedure

In front port applications, it is important to ensure that the placement of the DS125BR820 corresponds with the direction of the data flow, since the device is unidirectional. For egress applications, the DS125BR820 should be placed close to the connector cage, and for ingress applications, the DS125BR820 should be placed closer to the switch ASIC. Once the DS125BR820 placement is decided on the signal path, the repeater must be tuned. To tune the repeater, the settings mentioned in Table 11 (for Pin Mode) and Table 12 (for SMBus Modes) are recommended as a default starting point for most applications. Once these settings are configured, additional tuning of the EQ and, to a lesser extent, VOD may be required to optimize the repeater performance in order to meet the link training requirements for 40G-CR4 and eye mask requirements for 40G-SR4/LR4.

An example of a test configuration used to evaluate the DS125BR820 in this application can be seen in Figure 34. For more information about DS125BR820 front port applications, please refer to application note SNLA226:

front_port_setup_with_BR820.gifFigure 34. 10 GbE Transmitter with DS125BR820 QSFP+ Test Board

8.2.2.3 Application Performance Plots

eye_nPPI_df1610-05in4mil-br820-eqLevel2-n3-34-n1.gif
A. DS125BR820 Settings: EQA = Level 2, VODA = Level 6
Figure 35. nPPI Eye Mask Performance with 5 Inch 4-Mil FR4 Input Trace, Test Pattern = PRBS-9, 10.3125 Gbps
eye_nPPI_df1610-15in5mil-br820-eqLevel3-n5-42-n9.gif
A. DS125BR820 Settings: EQA = Level 3, VODA = Level 6
Figure 37. nPPI Eye Mask Performance with 15 Inch 5-Mil FR4 Input Trace, Test Pattern = PRBS-9, 10.3125 Gbps
jit-df1610-05in4mil-br820-eqLevel2-n3-34-n1.gif
A. DS125BR820 Settings: EQA = Level 2, VODA = Level 6
Figure 36. nPPI Jitter Performance with 5 Inch 4-Mil FR4 Input Trace, Test Pattern = PRBS-9, 10.3125 Gbps
jit-df1610-15in5mil-br820-eqlevel3-n5-42-n9.gif
A. DS125BR820 Settings: EQA = Level 3, VODA = Level 6
Figure 38. nPPI Jitter Performance with 15 Inch 5-Mil FR4 Input Trace, Test Pattern = PRBS-9, 10.3125 Gbps

8.2.3 PCIe Board Applications (PCIe Gen-3)

The DS125BR820 can be used to extend trace length on motherboards and line cards in PCIe Gen-3 applications. The high linearity of the DS125BR820 aids in the link training protocol required by PCIe Gen-3 at 8 Gbps in accordance with PCI-SIG standards. For PCIe Gen-3, preservation of the pre-cursor and post-cursor Tx FIR presets (P1-P10) is crucial to successful signal transmission from motherboard system root complex to line card ASIC or Embedded Processor. Below is a typical example of the DS125BR820 used in a PCIe application:

PCIe_Typical_Diagram.gifFigure 39. Typical PCIe Gen-3 Configuration Diagram

8.2.3.1 Design Requirements

As with any high speed design, there are many factors that influence the overall performance. Please reference Design Requirements in the Generic High Speed Repeater application section for a list of critical areas for consideration and study during design.

8.2.3.2 Design Procedure

In PCIe Gen-3 applications, there is a large range of flexibility regarding the placement of the DS125BR820 in the signal path due to the high linearity of the device. If the PCIe slot must also support lower speeds like PCIe Gen-1 (2.5 Gbps) and Gen-2 (5.0 Gbps), it is recommended to place the DS125BR820 closer to the endpoint Rx. Once the DS125BR820 is placed on the signal path, the repeater must be tuned. To tune the repeater, the settings mentioned in Table 11 (for Pin Mode) and Table 12 (for SMBus Modes) are recommended as a default starting point for most applications. Once these settings are configured, additional tuning of the EQ and, to a lesser extent, VOD may be required to optimize the repeater performance to pass link training preset requirements for PCIe Gen-3.

An example of a test configuration used to evaluate the DS125BR820 in this application can be seen in Figure 40. For more information about DS125BR820 PCIe applications, please refer to application note SNLA227:

PCIe_Gen3_Add_In_Diagram.gifFigure 40. Typical PCIe Gen-3 Add-In Card Test Diagram

8.2.3.3 Application Performance Plots

10in_eq0_preset7_transition.gif
A. No Repeater Used
Composite Eye Height: 50.39 mV
Minimum Eye Width: 49.87 ps
Overall SigTest Result: Fail
Figure 41. PCIe Gen-3, Preset 7, Transition Eye
TL1 = 10 Inch 4-Mil FR4 Trace, No TL2
No Repeater, 8 Gbps
10in_eq0_preset7_non-transition.gif
A. No Repeater Used
Composite Eye Height: 50.39 mV
Minimum Eye Width: 49.87 ps
Overall SigTest Result: Fail
Figure 43. PCIe Gen-3, Preset 7, Non-Transition Eye
TL1 = 10 Inch 4-Mil FR4 Trace, No TL2
No Repeater, 8 Gbps
10inI_5inO_eq0_preset7_transition.gif
A. No Repeater Used
Composite Eye Height: 0.057 mV
Minimum Eye Width: 37.66 ps
Overall SigTest Result: Fail
Figure 45. PCIe Gen-3, Preset 7, Transition Eye
TL1 = 10 Inch 4-Mil FR4 Trace,
TL2 = 5 Inch 4-Mil FR4 Trace
No Repeater, 8 Gbps
10inI_5inO_eq0_preset7_non-transition.gif
A. No Repeater Used
Composite Eye Height: 0.057 mV
Minimum Eye Width: 37.66 ps
Overall SigTest Result: Fail
Figure 47. PCIe Gen-3, Preset 7, Non-Transition Eye
TL1 = 10 Inch 4-Mil FR4 Trace,
TL2 = 5 Inch 4-Mil FR4 Trace
No Repeater, 8 Gbps
10in_eq3_preset7_transition.gif
A. DS125BR820 Settings: EQA = Level 4, VODA = Level 6
Composite Eye Height: 112.2 mV
Minimum Eye Width: 83.82 ps
Overall SigTest Result: Pass
Figure 42. PCIe Gen-3, Preset 7, Transition Eye
TL1 = 10 Inch 4-Mil FR4 Trace, No TL2
DS125BR820, 8 Gbps
10in_eq3_preset7_non-transition.gif
A. DS125BR820 Settings: EQA = Level 4, VODA = Level 6
Composite Eye Height: 112.2 mV
Minimum Eye Width: 83.82 ps
Overall SigTest Result: Pass
Figure 44. PCIe Gen-3, Preset 7, Non-Transition Eye
TL1 = 10 Inch 4-Mil FR4 Trace, No TL2
DS125BR820, 8 Gbps
10inI_5inO_eq3_preset7_transition.gif
A. DS125BR820 Settings: EQA = Level 4, VODA = Level 6
Composite Eye Height: 77.26 mV
Minimum Eye Width: 78.24 ps
Overall SigTest Result: Pass
Figure 46. PCIe Gen-3, Preset 7, Transition Eye
TL1 = 10 Inch 4-Mil FR4 Trace,
TL2 = 5 Inch 4-Mil FR4 Trace
DS125BR820, 8 Gbps
10inI_5inO_eq3_preset7_non-transition.gif
A. DS125BR820 Settings: EQA = Level 4, VODA = Level 6
Composite Eye Height: 77.26 mV
Minimum Eye Width: 78.24 ps
Overall SigTest Result: Pass
Figure 48. PCIe Gen-3, Preset 7, Non-Transition Eye
TL1 = 10 Inch 4-Mil FR4 Trace,
TL2 = 5 Inch 4-Mil FR4 Trace
DS125BR820, 8 Gbps