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    基于TI公司的AM437x雙照相機參考設計

    來源: 中電網
    2019-04-02
    類別:消費電子
    eye 10108
    文章創建人 拍明芯城

    原標題:TI AM437x雙照相機參考設計

      TI公司的高性能處理器AM437x系列MCU是基于ARM Cortex-A9核,具有增強的3D圖像加速子系統POWERVR SGX以及用于包括工業通信協議如EtherCAT, PROFIBUS?, EnDat和其它協議的實時處理的協處理器,器件支持高級操作系統(HLOS),主要用在工業自動化,POS,手持無線電,測試測量,病人監護,手持數據終端,導航設備和條碼掃描儀.本文介紹了AM437x 系列主要特性和框圖, 雙照相機參考設計和AM437x GP EVM評估模塊主要特性,系統框圖,電路圖,材料清單和PCB設計文件.

      The TI AM437x high-performance processors are based on the ARM Cortex-A9 core. The processors are enhanced with 3D graphics acceleration for rich graphical user interfaces, as well as a co-processor for deterministic, real-time processing including industrial communication protocols, such as EtherCAT, PROFIBUS?, EnDat and others. The devices support high-level operating systems (HLOS). Linux? is available free of charge from TI. Other HLOSs are available from TI’s Design Network and ecosystem partners.

      These devices offer an upgrade to systems based on lower performance ARM cores and provide updated peripherals, including memory options such as QSPI-NOR and LPDDR2.

      The processors contain the subsystems shown in and a brief description of each follows.

      The processor subsystem is based on the ARM Cortex-A9 core, and the POWERVR SGX graphics accelerator subsystem provides 3D graphics acceleration to support display and advanced user interfaces.

      The programmable real-time unit subsystem and industrial communication subsystem (PRU-ICSS) is separate from the ARM core and allows independent operation and clocking for greater efficiency and flexibility. The PRU-ICSS enables additional peripheral interfaces and real-time protocols such as EtherCAT, PROFINET, EtherNet/IP, PROFIBUS, Ethernet Powerlink, Sercos, EnDat, and others. The PRU-ICSS enables EnDat and another industrial communication protocol in parallel. Additionally, the programmable nature of the PRU-ICSS, along with their access to pins, events and all SoC resources, provides flexibility in implementing fast real-time responses, specialized data handling operations, custom peripheral interfaces, and in offloading tasks from the other processor cores of the system-on-chip (SoC).

      High-performance interconnects provide high-bandwidth data transfers for multiple initiators to the internal and external memory controllers and to on-chip peripherals. The device also offers a comprehensive clock-management scheme.

      One on-chip analog to digital converter (ADC0) can couple with the display subsystem to provide an integrated touch-screen solution. The other ADC (ADC1) can combine with the pulse width module to create a closed-loop motor control solution.

      The real-time clock (RTC) provides a clock reference on a separate power domain. The clock reference enables battery backed clock reference.

      The camera interface offers configuration for a single or dual camera parallel port.

      Cryptographic acceleration is available in every AM437x device. Secure boot can also be made available for anti-cloning and illegal software update protection. For more information about secure boot, contact your TI sales representative.

      AM437x 系列主要特性:

      Highlights

      Up to 1000-MHz Sitara ARM Cortex-A9 32-Bit RISC processor

      NEON SIMD Coprocessor and Vector Floating Point (VFPv3) Coprocessor

      32KB of Both L1 Instruction and Data Cache

      256KB of L2 Cache or L3 RAM

      32-Bit LPDDR2, DDR3, and DDR3L Support

      General-Purpose Memory Support (NAND, NOR, SRAM) Supporting Up to 16-bit ECC

      SGX530 Graphics Engine

      Display Subsystem

      Programmable Real-Time Unit Subsystem and Industrial Communication Subsystem (PRU-ICSS)

      Real-Time Clock (RTC)

      Up to Two USB 2.0 High-Speed OTG Ports with Integrated PHY

      10, 100, and 1000 Ethernet Switch Supporting Up to Two Ports

      Serial Interfaces:

      Two Controller Area Network (CAN) Ports

      Six UARTs, Two McASPs, Five McSPI, Three I2C Ports, One QSPI and One HDQ or 1-Wire

      Security

      Crypto Hardware Accelerators (AES, SHA, RNG, DES and 3DES)

      Secure Boot

      Two 12-Bit Successive Approximation Register (SAR) ADCs

      Up to Three 32-Bit Enhanced Capture Modules (eCAP)

      Up to Three Enhanced Quadrature Encoder Pulse Modules (eQEP)

      Up to Six Enhanced High-Resolution PWM Modules (eHRPWM)

      MPU Subsystem

      Up to 1000-MHz ARM Cortex-A9 32-Bit RISC Microprocessor

      32KB of Both L1 Instruction and Data Cache

      256KB of L2 Cache (Option to Configure as L3 RAM)

      256KB of On-Chip Boot ROM

      64KB On-Chip RAM

      Secure Control Module (SCM)

      Emulation and Debug

      JTAG

      Embedded Trace Buffer

      Interrupt Controller

      On-Chip Memory (Shared L3 RAM)

      256KB of General Purpose On-Chip Memory Controller (OCMC) RAM

      Accessible to All Masters

      Supports Retention for Fast Wakeup

      Up to 512KB of Total Internal RAM

      (256KB of ARM Memory Configured as L3 RAM + 256KB of OCMC RAM)

      External Memory Interfaces (EMIF)

      DDR Controllers:

      LPDDR2: 266-MHz Clock (LPDDR2-533 Data Rate)

      DDR3 and DDR3L: 400-MHz Clock (DDR-800 Data Rate)

      32-Bit Data Bus

      2GB of Total Addressable Space

      Supports One x32, Two x16, or Four x8 Memory Device Configurations

      General-Purpose Memory Controller (GPMC)

      Flexible 8- and 16-Bit Asynchronous Memory Interface with Up to Seven Chip Selects (NAND, NOR, Muxed-NOR, and SRAM)

      Uses BCH Code to Support 4-, 8-, or 16-Bit ECC

      Uses Hamming Code to Support 1-Bit ECC

      Error Locator Module (ELM)

      Used with the GPMC to Locate Addresses of Data Errors from Syndrome Polynomials Generated Using a BCH Algorithm

      Supports 4-, 8-, and 16-Bit Per 512-Byte Block Error Location Based on BCH Algorithms

      Programmable Real-Time Unit Subsystem and Industrial Communication Subsystem (PRU-ICSS)

      Supports Protocols such as EtherCAT, PROFIBUS, PROFINET, and EtherNet/IP?, EnDat 2.2, and More

      Two Programmable Real-Time Units (PRUs) Subsystems

      32-Bit Load and Store RISC Processor Capable of Running at 200 MHz

      12KB (PRU-ICSS1), 4KB (PRU-ICSS0) of Instruction RAM with Single-Error Detection (Parity)

      8KB (PRU-ICSS1), 4KB (PRU-ICSS0) of Data RAM with Single-Error Detection (Parity)

      Single-Cycle 32-Bit Multiplier with 64-Bit Accumulator

      Enhanced GPIO Module Provides Shift-In and Shift-Out Support and Parallel Latch on External Signal

      12KB (PRU-ICSS1 only) of Shared RAM with Single-Error Detection (Parity)

      Three 120-Byte Register Banks Accessible by Each PRU

      Interrupt Controller Module (INTC) for Handling System Input Events

      Local Interconnect Bus for Connecting Internal and External Masters to the Resources Inside the PRU-ICSS

      Peripherals Inside the PRU-ICSS

      One UART Port with Flow Control Pins, Supports Up to 12 Mbps

      One Enhanced Capture (eCAP) Module

      Two MII Ethernet Ports that Support Industrial Ethernet, such as EtherCAT

      One MDIO Port

      Industrial Communication is Supported by Two PRU-ICSS Subsystems

      Power Reset and Clock Management (PRCM) Module

      Controls the Entry and Exit of Deep-Sleep Modes

      Responsible for Sleep Sequencing, Power Domain Switch-Off Sequencing, Wake-Up Sequencing, and Power Domain Switch-On Sequencing

      Clocks

      Integrated High-Frequency Oscillator Used to Generate a Reference Clock (19.2, 24, 25, and 26 MHz) for Various System and Peripheral Clocks

      Supports Individual Clock Enable and Disable Control for Subsystems and Peripherals to Facilitate Reduced Power Consumption

      Five ADPLLs to Generate System Clocks (MPU Subsystem, DDR Interface, USB, and Peripherals (MMC and SD, UART, SPI, I2C), L3, L4, Ethernet, GFX (SGX530), and LCD Pixel Clock)

      Power

      Two Non-Switchable Power Domains (RTC and Wake-Up Logic (WAKE-UP))

      Three Switchable Power Domains (MPU Subsystem, SGX530 (GFX), Peripherals and Infrastructure (PER))

      Implements SmartReflex Class 2B for Core Voltage scaling Based On Die Temperature, Process Variation and Performance (Adaptive Voltage Scaling (AVS))

      Dynamic Voltage Frequency Scaling (DVFS)

      Real-Time Clock (RTC)

      Real-Time Date (Day, Month, Year, and Day of Week) and Time (Hours, Minutes, and Seconds) Information

      Internal 32.768-kHz Oscillator, RTC Logic, and 1.1-V Internal LDO

      Independent Power-On-Reset (RTC_PWRONRSTn) Input

      Dedicated Input Pin (RTC_WAKEUP) for External Wake Events

      Programmable Alarm Can Generate Internal Interrupts to the PRCM for Wake Up or Cortex-A9 for Event Notification

      Programmable Alarm Can Be Used with External Output (RTC_PMIC_EN) to Enable the Power Management IC to Restore Non-RTC Power Domains

      Peripherals

      Up to Two USB 2.0 High-Speed OTG Ports with Integrated PHY

      Up to Two Industrial Gigabit Ethernet MACs (10, 100, and 1000 Mbps)

      Integrated Switch

      Each MAC Supports MII, RMII, and RGMII and MDIO Interfaces

      Ethernet MACs and Switch Can Operate Independent of Other Functions

      IEEE 1588v2 Precision Time Protocol (PTP)

      Up to Two Controller-Area Network (CAN) Ports

      Supports CAN Version 2 Parts A and B

      Up to Two Multichannel Audio Serial Ports (McASP)

      Transmit and Receive Clocks Up to 50 MHz

      Up to Four Serial Data Pins Per McASP Port with Independent TX and RX Clocks

      Supports Time Division Multiplexing (TDM), Inter-IC Sound (I2S), and Similar Formats

      Supports Digital Audio Interface Transmission (SPDIF, IEC60958-1, and AES-3 Formats)

      FIFO Buffers for Transmit and Receive (256 Bytes)

      Up to Six UARTs

      All UARTs Support IrDA and CIR Modes

      All UARTs Support RTS and CTS Flow Control

      UART1 Supports Full Modem Control

      Up to Five Master and Slave McSPI Serial Interfaces

      McSPI0-McSPI2 Supports Up to Four Chip Selects

      McSPI3-McSPI4 Supports Up to Two Chip Selects

      Up to 48 MHz

      One Quad-SPI

      Supports eXecute In Place (XIP) from Serial NOR FLASH

      One Dallas 1-Wire? and HDQ Serial Interface

      Up to Three MMC, SD, and SDIO Ports

      1-, 4-, and 8-Bit MMC, SD, and SDIO Modes

      1.8- or 3.3-V Operation on All Ports

      Up to 48-MHz Clock

      Supports Card Detect and Write Protect

      Complies with MMC4.3 and SD and SDIO 2.0 Specifications

      Up to Three I2C Master and Slave Interfaces

      Standard Mode (Up to 100 kHz)

      Fast Mode (Up to 400 kHz)

      Up to Six Banks of General-Purpose I/O (GPIO)

      32 GPIOs per Bank (Multiplexed with Other Functional Pins)

      GPIOs Can be Used as Interrupt Inputs (Up to Two Interrupt Inputs per Bank)

      Up to Three External DMA Event Inputs That Can Also be Used as Interrupt Inputs

      Twelve 32-Bit General-Purpose Timers

      DMTIMER1 is a 1-ms Timer Used for Operating System (OS) Ticks

      DMTIMER4–DMTIMER7 are Pinned Out

      One Public Watchdog Timer

      One Free Running High Resolution 32-kHz Counter (synctimer32K)

      SGX530 3D Graphics Engine

      Tile-Based Architecture Delivering Up to 20M Poly/sec

      Universal Scalable Shader Engine is a Multi-Threaded Engine Incorporating Pixel and Vertex Shader Functionality

      Advanced Shader Feature Set in Excess of Microsoft VS3.0, PS3.0, and OGL2.0

      Industry Standard API Support of Direct3D Mobile, OGL-ES 1.1 and 2.0, and OpenVG 1.0

      Fine-Grained Task Switching, Load Balancing, and Power Management

      Advanced Geometry DMA-Driven Operation for Minimum CPU Interaction

      Programmable High-Quality Image Anti-Aliasing

      Fully Virtualized Memory Addressing for OS Operation in a Unified Memory Architecture

      Display Subsystem

      Display Modes

      Programmable Pixel Memory Formats (Palletized: 1-, 2-, 4-, and 8-Bit Per Pixel; RGB 16- and 24-Bit Per Pixel; and YUV 4:2:2)

      256 x 24-Bit Entries Palette in RGB

      Up to 2048 x 2048 Resolution

      Display Support

      Four Types of Displays Are Supported: Passive and Active Colors; Passive and Active Monochromes

      4- and 8-Bit Monochrome Passive Panel Interface Support (15 Grayscale Levels Supported Using Dithering Block)

      RGB 8-Bit Color Passive Panel Interface Support (3,375 Colors Supported for Color Panel Using Dithering Block)

      RGB 12-, 16-, 18-, and 24-Bit Active Panel Interface Support (Replicated or Dithered Encoded Pixel Values)

      Remote Frame Buffer (Embedded in the LCD Panel) Support through the RFBI Module

      Partial Refresh of the Remote Frame Buffer through the RFBI Module

      Partial Display

      Multiple Cycles Output Format on 8-, 9-, 12-, and 16-Bit Interface (TDM)

      Signal Processing

      Overlay and Windowing Support for One Graphics Layer (RGB or CLUT) and Two Video Layers (YUV 4:2:2, RGB16, and RGB24)

      RGB 24-bit Support on the Display Interface, Optionally Dithered to RGB 18-Bit Pixel Output Plus 6-Bit Frame Rate Control (Spatial and Temporal)

      Transparency Color Key (Source and Destination)

      Synchronized Buffer Update

      Gamma Curve Support

      Multiple-Buffer Support

      Cropping Support

      Color Phase Rotation

      Two 12-Bit Successive Approximation Register (SAR) ADCs (ADC0, ADC1)

      867K Samples Per Second

      Input Can Be Selected from Any of the Eight Analog Inputs Multiplexed Through an 8:1 Analog Switch

      ADC0 Can Be Configured to Operate as a 4-, 5-, or 8-Wire Resistive Touch Screen Controller (TSC)

      Up to Three 32-Bit Enhanced Capture Modules (eCAP)

      Configurable as Three Capture Inputs or Three Auxiliary PWM Outputs

      Up to Six Enhanced High-Resolution PWM Modules (eHRPWM)

      Dedicated 16-Bit Time-Base Counter with Time and Frequency Controls

      Configurable as Six Single-Ended, Six Dual-Edge Symmetric, or Three Dual-Edge Asymmetric Outputs

      Up to Three 32-Bit Enhanced Quadrature Encoder Pulse (eQEP) Modules

      Device Identification

      Factory Programmable Electrical Fuse Farm (FuseFarm)

      Production ID

      Device Part Number (Unique JTAG ID)

      Device Revision (Readable by Host ARM)

      Feature Identification

      Debug Interface Support

      JTAG and cJTAG for ARM (Cortex-A9 and PRCM) and PRU-ICSS Debug

      Supports Real-Time Trace Pins (for Cortex-A9)

      64KB Embedded Trace Buffer (ETB)

      Supports Device Boundary Scan

      Supports IEEE 1500

      DMA

      On-Chip Enhanced DMA Controller (EDMA) Has Three Third-Party Transfer Controllers (TPTC) and One Third-Party Channel Controller (TPCC), Which Supports Up to 64 Programmable Logical Channels and Eight QDMA Channels

      EDMA is Used for:

      Transfers to and from On-Chip Memories

      Transfers to and from External Storage (EMIF, General-Purpose Memory Controller, and Slave Peripherals)

      Inter-Processor Communication (IPC)

      Integrates Hardware-Based Mailbox for IPC and Spinlock for Process Synchronization Between the Cortex-A9, PRCM, and PRU-ICSS

      Boot Modes

      Boot Mode is Selected via Boot Configuration Pins Latched on the Rising Edge of the PWRONRSTn Reset Input Pin

      Camera

      Dual Port 8- and 10-Bit BT656 Interface

      Dual Port 8- and 10-Bit Including External Syncs

      Single Port 12-Bit

      YUV422/RGB422 and BT656 Input Format

      RAW Format

      Pixel Clock Rate Up to 75 MHz

      Package

      491-pin BGA Package (17x17 mm) (ZDN Suffix), 0.65-mm Ball Pitch with Via Channel Array Technology to Enable Low-Cost Routing

      AM437x系列主要應用:

      Patient Monitoring

      Navigation Equipment

      Industrial Automation

      Portable Data Terminals

      Bar Code Scanners

      Point of Service

      Portable Mobile Radio

      Test and Measurement

      圖1. AM437x功能框圖

      AM437x雙照相機參考設計

      Developers looking for camera support on the Sitara AM437x processors can use this reference design to jump start their development. The AM437x camera interface is a parallel port that can be configured as a single or dual camera interface. The dual camera configuration enables the use of two simultaneous camera inputs.

      The AM437x GP EVM is a standalone test, development, and evaluation module system that enables developers to write software and develop hardware around an AM437x processor subsystem. The main elements of the AM437x subsystem are already available on the base board of the EVM, which gives developers the basic resources needed for most general purpose type projects that encompass the AM437x as the main processor. Furthermore, additional, "typical-type" peripherals are built into the EVM, such as memory, sensors, LCD, Ethernet physical layer (PHY), and so on, so that prospective systems can be modeled quickly without significant additional hardware resources.

      AM437x GP EVM評估模塊主要特性:

      Two simultaneous 2-Megapixel SOC Cameras

      Cameras connected to the integrated Camera Interface (VPFE) of the Sitara AM437x processor

      Dual Port 8-bit interface with BT656 or external synch signals

      YUV422/RGB422, BT656, and RAW interface formats

      Complete sub-system reference with schematics, BOM, design files, and HW User’s Guide implemented on a fully assembled board developed for testing and validation.

      圖2. AM437x GP EVM評估模塊外形圖

      圖3. AM437x GP EVM評估模塊系統框圖

      圖4. AM437x 雙照相機參考設計板電路圖

    圖5. AM437x 雙照相機參考通用EVM板電路圖(1)

      圖6. AM437x 雙照相機參考通用EVM板電路圖(2)

      圖7. AM437x 雙照相機參考通用EVM板電路圖(3)


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