Datasheet VSC7415 (Microchip) - 2
| Manufacturer | Microchip |
| Description | 6-Port SGMII Gigabit Ethernet Switch with VeriTime and Integrated DPLL and Gigabit Ethernet PHYs |
| Pages / Page | 444 / 2 — Microsemi Headquarters. About Microsemi |
| File Format / Size | PDF / 6.2 Mb |
| Document Language | English |
Microsemi Headquarters. About Microsemi
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Microsemi makes no warranty, representation, or guarantee regarding the information contained herein or the suitability of its products and services for any particular purpose, nor does Microsemi assume any liability whatsoever arising out of the application or use of any product or circuit. The products sold hereunder and any other products sold by Microsemi have been subject to limited testing and should not be used in conjunction with mission-critical equipment or applications. Any performance specifications are believed to be reliable but are not verified, and Buyer must conduct and complete all
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performance and other testing of the products, alone and together with, or installed in, any end-products. Buyer shall not rely on any data and performance specifications or parameters provided by Microsemi. It is the Buyer’s responsibility to One Enterprise, Aliso Viejo, independently determine suitability of any products and to test and verify the same. The information provided by Microsemi CA 92656 USA hereunder is provided “as is, where is” and with all faults, and the entire risk associated with such information is entirely Within the USA: +1 (800) 713-4113 with the Buyer. Microsemi does not grant, explicitly or implicitly, to any party any patent rights, licenses, or any other IP Outside the USA: +1 (949) 380-6100 rights, whether with regard to such information itself or anything described by such information. Information provided in this Sales: +1 (949) 380-6136 document is proprietary to Microsemi, and Microsemi reserves the right to make any changes to the information in this Fax: +1 (949) 215-4996 document or to any products and services at any time without notice. Email: sales.support@microsemi.com www.microsemi.com
About Microsemi
©2019 Microsemi, a wholly owned Microsemi, a wholly owned subsidiary of Microchip Technology Inc. (Nasdaq: MCHP), offers a comprehensive portfolio of subsidiary of Microchip Technology Inc. All semiconductor and system solutions for aerospace & defense, communications, data center and industrial markets. rights reserved. Microsemi and the Products include high-performance and radiation-hardened analog mixed-signal integrated circuits, FPGAs, SoCs and Microsemi logo are registered trademarks of ASICs; power management products; timing and synchronization devices and precise time solutions, setting the world's Microsemi Corporation. All other trademarks standard for time; voice processing devices; RF solutions; discrete components; enterprise storage and communication and service marks are the property of their solutions, security technologies and scalable anti-tamper products; Ethernet solutions; Power-over-Ethernet ICs and respective owners. midspans; as well as custom design capabilities and services. Learn more at www.microsemi.com. VMDS-10447. 4.1 6/19 Document Outline 1 Revision History 1.1 Revision 4.1 1.2 Revision 4.0 2 Product Overview 2.1 General Features 2.1.1 Layer 2 and Layer 3 Forwarding 2.1.2 Timing and Synchronization 2.1.3 Quality of Service 2.1.4 Security 2.1.5 Management 2.1.6 Product Parameters 2.2 Applications 2.2.1 Wireless Backhaul 2.2.2 Small Cell Application 3 Functional Descriptions 3.1 Register Notations 3.2 Functional Overview 3.2.1 Frame Arrival in Ports and Port Modules 3.2.2 Basic Classification 3.2.3 Security and Control Protocol Classification 3.2.4 Policing 3.2.5 Layer 2 Forwarding 3.2.6 Layer 3 Forwarding 3.2.7 Shared Queue System and Hierarchical Scheduler 3.2.8 Rewriter and Frame Departure 3.2.9 CPU Port Module 3.2.10 Synchronous Ethernet and Precision Time Protocol (PTP) 3.2.11 CPU Subsystem 3.3 Frame Headers 3.3.1 Internal Frame Header Placement 3.3.2 Internal Frame Header Layout 3.3.3 VStaX Header 3.4 Port Numbering and Mappings 3.4.1 Supported SerDes Interfaces 3.4.2 Dual-Media Mode 3.4.3 Logical Port Numbers 3.5 SERDES1G 3.6 SERDES6G 3.7 Copper Transceivers 3.7.1 Register Access 3.7.2 Cat5 Twisted Pair Media Interface 3.7.3 Wake-On-LAN and SecureOn 3.7.4 Ethernet Inline Powered Devices 3.7.5 IEEE 802.3af PoE Support 3.7.6 ActiPHY™ Power Management 3.7.7 Testing Features 3.7.8 VeriPHY™ Cable Diagnostics 3.8 DEV1G and DEV2G5 Port Modules 3.8.1 MAC 3.8.2 Half-Duplex Mode 3.8.3 Physical Coding Sublayer (PCS) 3.8.4 Port Statistics 3.9 Assembler 3.9.1 Setting Up a Port in the Assembler 3.9.2 Setting Up a Port for Frame Injection 3.9.3 Setting Up MAC Control Sublayer PAUSE Frame Detection 3.9.4 Setting Up PFC 3.9.5 Setting Up Assembler Port Statistics 3.9.6 Setting Up the Loopback Path 3.10 Versatile Content-Aware Processor (VCAP) 3.10.1 Configuring VCAP 3.10.2 Wide VCAP Entries and Actions 3.10.3 Individual VCAPs 3.10.4 VCAP Programming Examples 3.11 Pipeline Points 3.11.1 Pipeline Definitions 3.12 Analyzer 3.12.1 Initializing the Analyzer 3.13 VCAP CLM Keys and Actions 3.13.1 Keys Overview 3.13.2 VCAP CLM X1 Key Details 3.13.3 VCAP CLM X2 Key Details 3.13.4 VCAP CLM X4 Key Details 3.13.5 VCAP CLM X8 Key Details 3.13.6 VCAP CLM X16 Key Details 3.13.7 VCAP CLM Actions 3.14 Analyzer Classifier 3.14.1 Basic Classifier 3.14.2 VCAP CLM Processing 3.14.3 QoS Mapping Table 3.14.4 Analyzer Classifier Diagnostics 3.15 VLAN and MSTP 3.15.1 Private VLAN 3.15.2 VLAN Pseudo Code 3.16 VCAP LPM: Keys and Action 3.16.1 VCAP LPM SGL_IP4 Key Details 3.16.2 VCAP LPM DBL_IP4 Key Details 3.16.3 VCAP LPM SGL_IP6 Key Details 3.16.4 VCAP LPM DBL_IP6 Key Details 3.16.5 VCAP LPM Actions 3.17 IP Processing 3.17.1 IP Source/Destination Guard 3.17.2 IP Routing 3.17.3 Statistics 3.17.4 IGMP/MLD Snooping Switch 3.18 VCAP IS2 Keys and Actions 3.18.1 VCAP IS2 Keys 3.18.2 VCAP IS2 Actions 3.19 Analyzer Access Control Lists 3.19.1 VCAP IS2 3.19.2 Analyzer Access Control List Frame Rewriting 3.20 Analyzer Layer 2 Forwarding and Learning 3.20.1 Analyzer MAC Table 3.20.2 MAC Table Updates 3.20.3 CPU Access to MAC Table 3.20.4 SCAN Command 3.20.5 Forwarding Lookups 3.20.6 Source Check and Automated Learning 3.20.7 Automated Aging (AUTOAGE) 3.20.8 Interrupt Handling 3.21 Analyzer Access Control Forwarding, Policing, and Statistics 3.21.1 Mask Handling 3.21.2 Policing 3.21.3 Analyzer Statistics 3.21.4 Analyzer sFlow Sampling 3.21.5 Mirroring 3.22 Shared Queue System and Hierarchical Scheduler 3.22.1 Analyzer Result 3.22.2 Buffer Control 3.22.3 Forwarding 3.22.4 Congestion Control 3.22.5 Queue Mapping 3.22.6 Queue Congestion Control 3.22.7 Scheduling 3.22.8 Queue System Initialization 3.22.9 Miscellaneous Features 3.23 Automatic Frame Injector 3.23.1 Injection Tables 3.23.2 Frame Table 3.23.3 Delay Triggered Injection 3.23.4 Timer Triggered Injection 3.23.5 Injection Queues 3.23.6 Adding Injection Frame 3.23.7 Starting Injection 3.23.8 Stopping Injection 3.23.9 Removing Injection Frames 3.23.10 Port Parameters 3.24 Rewriter 3.24.1 Rewriter Operation 3.24.2 Supported Ports 3.24.3 Supported Frame Formats 3.24.4 Rewriter Initialization 3.24.5 VCAP_ES0 Lookup 3.24.6 Mapping Tables 3.24.7 VLAN Editing 3.24.8 DSCP Remarking 3.24.9 VStaX Header Insertion 3.24.10 Forwarding to GCPU 3.24.11 Layer 3 Routing 3.24.12 Mirror Frames 3.24.13 Internal Frame Header Insertion 3.24.14 Frame Injection from Internal CPU 3.25 Disassembler 3.25.1 Setting Up Ports 3.25.2 Maintaining the Cell Buffer 3.25.3 Setting Up MAC Control Sublayer PAUSE Function 3.25.4 Setting up Flow Control in Half-Duplex Mode 3.25.5 Setting Up Frame Aging 3.25.6 Setting Up Transmit Data Rate Limiting 3.25.7 Error Detection 3.26 Layer 1 Timing 3.27 Hardware Time Stamping 3.27.1 One-Step Functions 3.27.2 Calculation Overview 3.27.3 Detecting Calculation Issues 3.27.4 Two-Step Functions 3.27.5 Time of Day Time Stamping 3.27.6 Time of Day Generation 3.27.7 Multiple PTP Time Domains 3.27.8 Register Interface to 1588 Functions 3.27.9 Configuring I/O Delays 3.28 SyncE and PTP DPLL Timing 3.28.1 Input Clock Selection 3.29 EEC/PEC Controller 3.29.1 Input Qualification Timers 3.29.2 Reference Clock Selection 3.29.3 Output Clock Synthesizers 3.29.4 Synchronizing IEEE 1588 Time Stamping 3.29.5 I/O Pin Mapping 3.30 VRAP Engine 3.30.1 VRAP Request Frame Format 3.30.2 VRAP Response Frame Format 3.30.3 VRAP Header Format 3.30.4 VRAP READ Command 3.30.5 VRAP READ-MODIFY-WRITE Command 3.30.6 VRAP IDLE Command 3.30.7 VRAP PAUSE Command 3.31 Energy Efficient Ethernet 3.32 CPU Injection and Extraction 3.32.1 Frame Injection 3.32.2 Frame Extraction 3.32.3 Forwarding to CPU 3.32.4 Automatic Frame Injection (AFI) 3.33 Priority-Based Flow Control (PFC) 3.33.1 PFC Pause Frame Generation 3.33.2 PFC Frame Reception 3.34 Protection Switching 3.34.1 Ethernet Ring Protection Switching 3.34.2 Link Aggregation 3.34.3 Port Protection Switching 3.35 Low Power Mode 3.35.1 One-Time Configurations for Low Power Mode 3.35.2 General Considerations in Low Power Mode 3.36 Clocking and Reset 3.36.1 Pin Strapping 4 VCore-III System and CPU Interfaces 4.1 VCore-III Configurations 4.2 Clocking and Reset 4.2.1 Watchdog Timer 4.3 Shared Bus 4.3.1 VCore-III Shared Bus Arbitration 4.3.2 Chip Register Region 4.3.3 SI Flash Region 4.3.4 DDR3/DDR3L Region 4.3.5 PCIe Region 4.4 VCore-III CPU 4.4.1 Little Endian and Big Endian Support 4.4.2 Software Debug and Development 4.5 External CPU Support 4.5.1 Register Access and Multimaster Systems 4.5.2 Serial Interface in Slave Mode 4.5.3 MIIM Interface in Slave Mode 4.5.4 Access to the VCore Shared Bus 4.5.5 Mailbox and Semaphores 4.6 PCIe Endpoint Controller 4.6.1 Accessing Endpoint Registers 4.6.2 Enabling the Endpoint 4.6.3 Base Address Registers Inbound Requests 4.6.4 Outbound Interrupts 4.6.5 Outbound Access 4.6.6 Power Management 4.6.7 Device Reset Using PCIe 4.7 Frame DMA 4.7.1 DMA Control Block Structures 4.7.2 Enabling and Disabling FDMA Channels 4.7.3 Channel Counters 4.7.4 FDMA Events and Interrupts 4.7.5 FDMA Extraction 4.7.6 FDMA Injection 4.7.7 Manual Mode 4.8 VCore-III System Peripherals 4.8.1 SI Boot Controller 4.8.2 SI Master Controller 4.8.3 DDR3/DDR3L Memory Controller 4.8.4 Timers 4.8.5 UARTs 4.8.6 Two-Wire Serial Interface 4.8.7 MII Management Controller 4.8.8 GPIO Controller 4.8.9 Serial GPIO Controller 4.8.10 Fan Controller 4.8.11 Temperature Sensor 4.8.12 Memory Integrity Monitor 4.8.13 Interrupt Controller 5 Registers 6 Electrical Specifications 6.1 DC Characteristics 6.1.1 Reference Clock 6.1.2 PLL Clock Output 6.1.3 DPLL Clocks 6.1.4 DDR3/DDR3L SDRAM Interface 6.1.5 SERDES1G 6.1.6 SERDES6G 6.1.7 GPIO, SI, JTAG, and Miscellaneous Signals 6.1.8 Thermal Diode 6.2 AC Characteristics 6.2.1 Reference Clock 6.2.2 PLL Clock Outputs 6.2.3 DPLL Clocks 6.2.4 Jitter Transfer 6.2.5 SERDES1G 6.2.6 SERDES6G 6.2.7 Reset Timing 6.2.8 MII Management 6.2.9 Serial Interface (SI) Boot Master Mode 6.2.10 Serial Interface (SI) Master Mode 6.2.11 Serial Interface (SI) for Slave Mode 6.2.12 DDR SDRAM Interface 6.2.13 JTAG Interface 6.2.14 Serial Inputs/Outputs 6.2.15 Recovered Clock Outputs 6.2.16 Two-Wire Serial Interface 6.2.17 IEEE 1588 Time Tick Outputs 6.3 Current and Power Consumption 6.3.1 Current Consumption 6.3.2 Power Consumption 6.3.3 Power Supply Sequencing 6.4 Operating Conditions 6.5 Stress Ratings 7 Pin Descriptions 7.1 Pin Diagram 7.2 Pins by Function 7.2.1 DDR SDRAM Interface 7.2.2 DPLL Clock 7.2.3 General-Purpose Inputs and Outputs 7.2.4 JTAG Interface 7.2.5 MII Management Interface 7.2.6 Miscellaneous 7.2.7 PCI Express Interface 7.2.8 Power Supplies and Ground 7.2.9 SERDES1G 7.2.10 SERDES6G 7.2.11 Serial CPU Interface 7.2.12 System Clock Interface 7.2.13 Twisted Pair Interface 7.3 Pins by Number 7.4 Pins by Name 8 Package Information 8.1 Package Drawing 8.2 Thermal Specifications 8.3 Moisture Sensitivity 9 Design Guidelines 9.1 Power Supplies 9.2 Power Supply Decoupling 9.2.1 Reference Clock 9.2.2 Single-Ended REFCLK Input 9.3 Interfaces 9.3.1 General Recommendations 9.3.2 SerDes Interfaces (SGMII, 2.5G) 9.3.3 Serial Interface 9.3.4 PCI Express Interface 9.3.5 Two-Wire Serial Interface 9.3.6 DDR3 SDRAM Interface 9.3.7 Thermal Diode External Connection 10 Design Considerations 11 Ordering Information
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performance and other testing of the products, alone and together with, or installed in, any end-products. Buyer shall not rely on any data and performance specifications or parameters provided by Microsemi. It is the Buyer’s responsibility to One Enterprise, Aliso Viejo, independently determine suitability of any products and to test and verify the same. The information provided by Microsemi CA 92656 USA hereunder is provided “as is, where is” and with all faults, and the entire risk associated with such information is entirely Within the USA: +1 (800) 713-4113 with the Buyer. Microsemi does not grant, explicitly or implicitly, to any party any patent rights, licenses, or any other IP Outside the USA: +1 (949) 380-6100 rights, whether with regard to such information itself or anything described by such information. Information provided in this Sales: +1 (949) 380-6136 document is proprietary to Microsemi, and Microsemi reserves the right to make any changes to the information in this Fax: +1 (949) 215-4996 document or to any products and services at any time without notice. Email: sales.support@microsemi.com www.microsemi.com
About Microsemi
©2019 Microsemi, a wholly owned Microsemi, a wholly owned subsidiary of Microchip Technology Inc. (Nasdaq: MCHP), offers a comprehensive portfolio of subsidiary of Microchip Technology Inc. All semiconductor and system solutions for aerospace & defense, communications, data center and industrial markets. rights reserved. Microsemi and the Products include high-performance and radiation-hardened analog mixed-signal integrated circuits, FPGAs, SoCs and Microsemi logo are registered trademarks of ASICs; power management products; timing and synchronization devices and precise time solutions, setting the world's Microsemi Corporation. All other trademarks standard for time; voice processing devices; RF solutions; discrete components; enterprise storage and communication and service marks are the property of their solutions, security technologies and scalable anti-tamper products; Ethernet solutions; Power-over-Ethernet ICs and respective owners. midspans; as well as custom design capabilities and services. Learn more at www.microsemi.com. VMDS-10447. 4.1 6/19 Document Outline 1 Revision History 1.1 Revision 4.1 1.2 Revision 4.0 2 Product Overview 2.1 General Features 2.1.1 Layer 2 and Layer 3 Forwarding 2.1.2 Timing and Synchronization 2.1.3 Quality of Service 2.1.4 Security 2.1.5 Management 2.1.6 Product Parameters 2.2 Applications 2.2.1 Wireless Backhaul 2.2.2 Small Cell Application 3 Functional Descriptions 3.1 Register Notations 3.2 Functional Overview 3.2.1 Frame Arrival in Ports and Port Modules 3.2.2 Basic Classification 3.2.3 Security and Control Protocol Classification 3.2.4 Policing 3.2.5 Layer 2 Forwarding 3.2.6 Layer 3 Forwarding 3.2.7 Shared Queue System and Hierarchical Scheduler 3.2.8 Rewriter and Frame Departure 3.2.9 CPU Port Module 3.2.10 Synchronous Ethernet and Precision Time Protocol (PTP) 3.2.11 CPU Subsystem 3.3 Frame Headers 3.3.1 Internal Frame Header Placement 3.3.2 Internal Frame Header Layout 3.3.3 VStaX Header 3.4 Port Numbering and Mappings 3.4.1 Supported SerDes Interfaces 3.4.2 Dual-Media Mode 3.4.3 Logical Port Numbers 3.5 SERDES1G 3.6 SERDES6G 3.7 Copper Transceivers 3.7.1 Register Access 3.7.2 Cat5 Twisted Pair Media Interface 3.7.3 Wake-On-LAN and SecureOn 3.7.4 Ethernet Inline Powered Devices 3.7.5 IEEE 802.3af PoE Support 3.7.6 ActiPHY™ Power Management 3.7.7 Testing Features 3.7.8 VeriPHY™ Cable Diagnostics 3.8 DEV1G and DEV2G5 Port Modules 3.8.1 MAC 3.8.2 Half-Duplex Mode 3.8.3 Physical Coding Sublayer (PCS) 3.8.4 Port Statistics 3.9 Assembler 3.9.1 Setting Up a Port in the Assembler 3.9.2 Setting Up a Port for Frame Injection 3.9.3 Setting Up MAC Control Sublayer PAUSE Frame Detection 3.9.4 Setting Up PFC 3.9.5 Setting Up Assembler Port Statistics 3.9.6 Setting Up the Loopback Path 3.10 Versatile Content-Aware Processor (VCAP) 3.10.1 Configuring VCAP 3.10.2 Wide VCAP Entries and Actions 3.10.3 Individual VCAPs 3.10.4 VCAP Programming Examples 3.11 Pipeline Points 3.11.1 Pipeline Definitions 3.12 Analyzer 3.12.1 Initializing the Analyzer 3.13 VCAP CLM Keys and Actions 3.13.1 Keys Overview 3.13.2 VCAP CLM X1 Key Details 3.13.3 VCAP CLM X2 Key Details 3.13.4 VCAP CLM X4 Key Details 3.13.5 VCAP CLM X8 Key Details 3.13.6 VCAP CLM X16 Key Details 3.13.7 VCAP CLM Actions 3.14 Analyzer Classifier 3.14.1 Basic Classifier 3.14.2 VCAP CLM Processing 3.14.3 QoS Mapping Table 3.14.4 Analyzer Classifier Diagnostics 3.15 VLAN and MSTP 3.15.1 Private VLAN 3.15.2 VLAN Pseudo Code 3.16 VCAP LPM: Keys and Action 3.16.1 VCAP LPM SGL_IP4 Key Details 3.16.2 VCAP LPM DBL_IP4 Key Details 3.16.3 VCAP LPM SGL_IP6 Key Details 3.16.4 VCAP LPM DBL_IP6 Key Details 3.16.5 VCAP LPM Actions 3.17 IP Processing 3.17.1 IP Source/Destination Guard 3.17.2 IP Routing 3.17.3 Statistics 3.17.4 IGMP/MLD Snooping Switch 3.18 VCAP IS2 Keys and Actions 3.18.1 VCAP IS2 Keys 3.18.2 VCAP IS2 Actions 3.19 Analyzer Access Control Lists 3.19.1 VCAP IS2 3.19.2 Analyzer Access Control List Frame Rewriting 3.20 Analyzer Layer 2 Forwarding and Learning 3.20.1 Analyzer MAC Table 3.20.2 MAC Table Updates 3.20.3 CPU Access to MAC Table 3.20.4 SCAN Command 3.20.5 Forwarding Lookups 3.20.6 Source Check and Automated Learning 3.20.7 Automated Aging (AUTOAGE) 3.20.8 Interrupt Handling 3.21 Analyzer Access Control Forwarding, Policing, and Statistics 3.21.1 Mask Handling 3.21.2 Policing 3.21.3 Analyzer Statistics 3.21.4 Analyzer sFlow Sampling 3.21.5 Mirroring 3.22 Shared Queue System and Hierarchical Scheduler 3.22.1 Analyzer Result 3.22.2 Buffer Control 3.22.3 Forwarding 3.22.4 Congestion Control 3.22.5 Queue Mapping 3.22.6 Queue Congestion Control 3.22.7 Scheduling 3.22.8 Queue System Initialization 3.22.9 Miscellaneous Features 3.23 Automatic Frame Injector 3.23.1 Injection Tables 3.23.2 Frame Table 3.23.3 Delay Triggered Injection 3.23.4 Timer Triggered Injection 3.23.5 Injection Queues 3.23.6 Adding Injection Frame 3.23.7 Starting Injection 3.23.8 Stopping Injection 3.23.9 Removing Injection Frames 3.23.10 Port Parameters 3.24 Rewriter 3.24.1 Rewriter Operation 3.24.2 Supported Ports 3.24.3 Supported Frame Formats 3.24.4 Rewriter Initialization 3.24.5 VCAP_ES0 Lookup 3.24.6 Mapping Tables 3.24.7 VLAN Editing 3.24.8 DSCP Remarking 3.24.9 VStaX Header Insertion 3.24.10 Forwarding to GCPU 3.24.11 Layer 3 Routing 3.24.12 Mirror Frames 3.24.13 Internal Frame Header Insertion 3.24.14 Frame Injection from Internal CPU 3.25 Disassembler 3.25.1 Setting Up Ports 3.25.2 Maintaining the Cell Buffer 3.25.3 Setting Up MAC Control Sublayer PAUSE Function 3.25.4 Setting up Flow Control in Half-Duplex Mode 3.25.5 Setting Up Frame Aging 3.25.6 Setting Up Transmit Data Rate Limiting 3.25.7 Error Detection 3.26 Layer 1 Timing 3.27 Hardware Time Stamping 3.27.1 One-Step Functions 3.27.2 Calculation Overview 3.27.3 Detecting Calculation Issues 3.27.4 Two-Step Functions 3.27.5 Time of Day Time Stamping 3.27.6 Time of Day Generation 3.27.7 Multiple PTP Time Domains 3.27.8 Register Interface to 1588 Functions 3.27.9 Configuring I/O Delays 3.28 SyncE and PTP DPLL Timing 3.28.1 Input Clock Selection 3.29 EEC/PEC Controller 3.29.1 Input Qualification Timers 3.29.2 Reference Clock Selection 3.29.3 Output Clock Synthesizers 3.29.4 Synchronizing IEEE 1588 Time Stamping 3.29.5 I/O Pin Mapping 3.30 VRAP Engine 3.30.1 VRAP Request Frame Format 3.30.2 VRAP Response Frame Format 3.30.3 VRAP Header Format 3.30.4 VRAP READ Command 3.30.5 VRAP READ-MODIFY-WRITE Command 3.30.6 VRAP IDLE Command 3.30.7 VRAP PAUSE Command 3.31 Energy Efficient Ethernet 3.32 CPU Injection and Extraction 3.32.1 Frame Injection 3.32.2 Frame Extraction 3.32.3 Forwarding to CPU 3.32.4 Automatic Frame Injection (AFI) 3.33 Priority-Based Flow Control (PFC) 3.33.1 PFC Pause Frame Generation 3.33.2 PFC Frame Reception 3.34 Protection Switching 3.34.1 Ethernet Ring Protection Switching 3.34.2 Link Aggregation 3.34.3 Port Protection Switching 3.35 Low Power Mode 3.35.1 One-Time Configurations for Low Power Mode 3.35.2 General Considerations in Low Power Mode 3.36 Clocking and Reset 3.36.1 Pin Strapping 4 VCore-III System and CPU Interfaces 4.1 VCore-III Configurations 4.2 Clocking and Reset 4.2.1 Watchdog Timer 4.3 Shared Bus 4.3.1 VCore-III Shared Bus Arbitration 4.3.2 Chip Register Region 4.3.3 SI Flash Region 4.3.4 DDR3/DDR3L Region 4.3.5 PCIe Region 4.4 VCore-III CPU 4.4.1 Little Endian and Big Endian Support 4.4.2 Software Debug and Development 4.5 External CPU Support 4.5.1 Register Access and Multimaster Systems 4.5.2 Serial Interface in Slave Mode 4.5.3 MIIM Interface in Slave Mode 4.5.4 Access to the VCore Shared Bus 4.5.5 Mailbox and Semaphores 4.6 PCIe Endpoint Controller 4.6.1 Accessing Endpoint Registers 4.6.2 Enabling the Endpoint 4.6.3 Base Address Registers Inbound Requests 4.6.4 Outbound Interrupts 4.6.5 Outbound Access 4.6.6 Power Management 4.6.7 Device Reset Using PCIe 4.7 Frame DMA 4.7.1 DMA Control Block Structures 4.7.2 Enabling and Disabling FDMA Channels 4.7.3 Channel Counters 4.7.4 FDMA Events and Interrupts 4.7.5 FDMA Extraction 4.7.6 FDMA Injection 4.7.7 Manual Mode 4.8 VCore-III System Peripherals 4.8.1 SI Boot Controller 4.8.2 SI Master Controller 4.8.3 DDR3/DDR3L Memory Controller 4.8.4 Timers 4.8.5 UARTs 4.8.6 Two-Wire Serial Interface 4.8.7 MII Management Controller 4.8.8 GPIO Controller 4.8.9 Serial GPIO Controller 4.8.10 Fan Controller 4.8.11 Temperature Sensor 4.8.12 Memory Integrity Monitor 4.8.13 Interrupt Controller 5 Registers 6 Electrical Specifications 6.1 DC Characteristics 6.1.1 Reference Clock 6.1.2 PLL Clock Output 6.1.3 DPLL Clocks 6.1.4 DDR3/DDR3L SDRAM Interface 6.1.5 SERDES1G 6.1.6 SERDES6G 6.1.7 GPIO, SI, JTAG, and Miscellaneous Signals 6.1.8 Thermal Diode 6.2 AC Characteristics 6.2.1 Reference Clock 6.2.2 PLL Clock Outputs 6.2.3 DPLL Clocks 6.2.4 Jitter Transfer 6.2.5 SERDES1G 6.2.6 SERDES6G 6.2.7 Reset Timing 6.2.8 MII Management 6.2.9 Serial Interface (SI) Boot Master Mode 6.2.10 Serial Interface (SI) Master Mode 6.2.11 Serial Interface (SI) for Slave Mode 6.2.12 DDR SDRAM Interface 6.2.13 JTAG Interface 6.2.14 Serial Inputs/Outputs 6.2.15 Recovered Clock Outputs 6.2.16 Two-Wire Serial Interface 6.2.17 IEEE 1588 Time Tick Outputs 6.3 Current and Power Consumption 6.3.1 Current Consumption 6.3.2 Power Consumption 6.3.3 Power Supply Sequencing 6.4 Operating Conditions 6.5 Stress Ratings 7 Pin Descriptions 7.1 Pin Diagram 7.2 Pins by Function 7.2.1 DDR SDRAM Interface 7.2.2 DPLL Clock 7.2.3 General-Purpose Inputs and Outputs 7.2.4 JTAG Interface 7.2.5 MII Management Interface 7.2.6 Miscellaneous 7.2.7 PCI Express Interface 7.2.8 Power Supplies and Ground 7.2.9 SERDES1G 7.2.10 SERDES6G 7.2.11 Serial CPU Interface 7.2.12 System Clock Interface 7.2.13 Twisted Pair Interface 7.3 Pins by Number 7.4 Pins by Name 8 Package Information 8.1 Package Drawing 8.2 Thermal Specifications 8.3 Moisture Sensitivity 9 Design Guidelines 9.1 Power Supplies 9.2 Power Supply Decoupling 9.2.1 Reference Clock 9.2.2 Single-Ended REFCLK Input 9.3 Interfaces 9.3.1 General Recommendations 9.3.2 SerDes Interfaces (SGMII, 2.5G) 9.3.3 Serial Interface 9.3.4 PCI Express Interface 9.3.5 Two-Wire Serial Interface 9.3.6 DDR3 SDRAM Interface 9.3.7 Thermal Diode External Connection 10 Design Considerations 11 Ordering Information
