黑金基于XILINX ZYNQ7000开发平台的开发板2016款正式发布了,型号为:AX7020 。此款开发平台是XILINX的Zynq7000 SOC 芯片的解决方案。它采用ARM+FPGA SOC技术将双核ARM Cortex-A9 和FPGA 可编程逻辑集成在一颗芯片上。它采用的是Xilinx的Zynq7000系列XC7Z020-2CLG400I作为核心处理器,在ARM和FPGA上分别具有丰富的硬件资源和外围接口。设计上坚持“精致、实用、简洁”的设计理念,它不但适合于软件工作人员的前期的软件验证,也适合于硬件开发人员的硬件设计即软硬件的系统协作,加快项目的开发进程。 .. image:: images/media/image2.png :width: 6.76389in :height: 5.10069in 图1-1 ZYNQ开发板全貌 开发板简介 =========== 在这里,对这款ZYNQ7000开发平台AX7020进行简单的功能介绍。 此款开发板使用的是Xilinx公司的Zynq7000系列的芯片,型号为XC7Z020-2CLG400I,400个引脚的FBGA封装。ZYNQ7000芯片可分成处理器系统部分Processor System(PS)和可编程逻辑部分Programmable Logic(PL)。在AX7020开发板上,ZYNQ7000的PS部分和PL部分都搭载了丰富的外部接口和设备,方便用户的使用和功能验证。另外开发板上集成了Xilinx USB Cable下载器电路,用户只要用一个USB线就可以对开发板进行下载和调试。图1-2为整个AX7020整个系统的结构示意图: .. image:: images/media/image3.png 图1-2 AX7020结构示意图 通过这个示意图,我们可以看到,我们这个开发平台所能含有的接口和功能。 - +5V电源输入,最大2A电流保护; - Xilinx ARM+FPGA芯片Zynq-7000 XC7Z020-2CLG400I - 两片大容量的4Gbit(共8Gbit)高速DDR3 SDRAM,可作为ZYNQ芯片数据的缓存,也可以作为操作系统运行的内存; - 一片256Mbit的QSPI FLASH, 可用作ZYNQ芯片的系统文件和用户数据的存储; - 一路10/100M/1000M以太网RJ-45接口, 可用于和电脑或其它网络设备进行以太网数据交换; - 一路HDMI 图像视频输入输出接口, 能实现1080P的视频图像传输; - 一路高速USB2.0 HOST接口, 可用于开发板连接鼠标、键盘和U盘等USB外设; - 一路高速USB2.0 OTG接口, 用于和PC或USB设备的OTG通信; - 一路USB Uart接口, 用于和PC或外部设备的串口通信; - 一片的RTC实时时钟,配有电池座,电池的型号为CR1220。 - 一片IIC接口的EEPROM 24LC04; - 6个用户发光二极管LED, 2个PS控制,4个PL控制; - 7个按键,1个CPU复位按键,2个PS控制按键,4个PL控制按键; - 板载一个33.333Mhz的有源晶振,给PS系统提供稳定的时钟源,一个50MHz的有源晶振,为PL逻辑提供额外的时钟; - 2路40针的扩展口(2.54mm间距),用于扩展ZYNQ的PL部分的IO。可以接7寸TFT模块、摄像头模块和AD/DA模块等扩展模块; - 一个12针的扩展口(2.54mm间距),用于扩展ZYNQ的PS系统的MIO; - 一路USB JTAG口,通过USB线及板载的JTAG电路对ZYNQ系统进行调试和下载。 .. 1路Micro SD卡座(开发板背面),用于存储操作系统镜像和文件系统。 结构尺寸 ======== 开发板的尺寸为精简的130mm x 90mm, PCB采用8层板设计。板子四周有4个螺丝定位孔,用于固定开发板,定位孔的孔径为3.5mm(直径),资料中提供dxf结构图。 .. image:: images/media/image4.png :width: 6.37292in :height: 4.15347in 电源 ==== 电源输入:开发板供电电压为DC5V,请使用开发板自带的电源,不要用其他规格的电源,以免损坏开发板。开发板上的电源设计示意图如下: |image2|\ 图3-1原理图中电源接口部分 开发板通过+5V供电, 通过四路DC/DC电源芯片TLV62130RGT转化成+3.3V,+1.5V,+1.8V,+1.0V四路电源, 每路输出电流可高达3A。通过一路LDO SPX3819M5-3-3产生VCCIO电源,VCCIO最要是针对ZYNQ的BANK35进行供电,通过更换其它的LDO芯片,使得BANK35的IO适应不同的电压标准。1.5V通过TI的TPS51200生成DDR3需要的VTT和VREF电压。各个电源分配的功能如下表所示: +--------------+-------------------------------------------------------+ | **电源** | **功能** | +--------------+-------------------------------------------------------+ | +3.3V | ZYNQ VCCIO, 以太网,串口,HDMI, RTC,FLASH, | | | EEPROM以及SD card | +--------------+-------------------------------------------------------+ | +1.8V | ZYNQ 辅助电压, ZYNQ PLL, ZYNQ Bank501 VCCIO, | | | 以太网,USB2.0 | +--------------+-------------------------------------------------------+ | +1.0V | ZYNQ,的核心电压 | +--------------+-------------------------------------------------------+ | +1.5V | DDR3, ZYNQ Bank502 | +--------------+-------------------------------------------------------+ | VREF, VTT | DDR3 | +--------------+-------------------------------------------------------+ | VCCIO | ZYNQ Bank35 | +--------------+-------------------------------------------------------+ 因为ZYNQ的PS和PL部分的电源有上电顺序的要求,在电路设计中,我们已经按照ZYQN的电源要求设计,上电依次为1.0V -> 1.8V -> 1.5 V -> 3.3V -> VCCIO,图3-2为电源的电路设计: .. image:: images/media/image6.png :width: 6.7625in :height: 3.71181in 图3-2 开发板的电源设计 我们在设计PCB的时候,采用8层PCB,预留了独立的电源层和GND层,使得整个开发板的电源,具有非常好的稳定性。在PCB板上我们预留了各个电源的测试点,以便用户确认板上的电压。 .. image:: images/media/image7.png :width: 2.13542in :height: 1.17708in 图 3-3 实物图中的电源测试点 ZYNQ7000 ======== 开发板使用的是Xilinx公司的Zynq7000系列的芯片,型号为XC7Z020-2CLG400I。芯片的PS系统集成了两个ARM Cortex™-A9处理器,AMBA®互连,内部存储器,外部存储器接口和外设。这些外设主要包括USB总线接口,以太网接口,SD/SDIO接口,I2C总线接口,CAN总线接口,UART接口,GPIO等。PS可以独立运行并在上电或复位下启动。ZYNQ7000芯片的总体框图如图4-1所示 .. image:: images/media/image8.png :width: 6.02292in :height: 3.46458in 图4-1 ZYNQ7000芯片的总体框图 其中PS系统部分的主要参数如下: - 基于ARM 双核CortexA9 的应用处理器 - 每个CPU 32KB 1级指令和数据缓存,512KB 2级缓存 2个CPU共享 - 片上boot ROM和256KB 片内RAM - 外部存储接口,支持16/32 bit DDR2、DDR3接口 - 两个千兆网卡支持:发散-聚集DMA ,GMII,RGMII,SGMII接口 - 两个USB2.0 OTG接口,每个最多支持12节点 - 两个CAN2.0B总线接口 - 两个SD卡、SDIO、MMC兼容控制器 - 2个SPI,2个UARTs,2个I2C接口 - 4组32bit GPIO,54(32+22)作为PS系统IO,64连接到PL - PS内和PS到PL的高带宽连接 其中PL逻辑部分的主要参数如下: - 逻辑单元Logic Cells:85K - 查找表LUTs: 53,200 - 触发器(flip-flops): 106,400 - 乘法器18x25MACCs:220 - Block RAM:4.9 Mb - 两个AD转换器,可以测量片上电压、温度感应和高达17外部差分输入通道,1MBPS XC7Z020-2CLG400I芯片为BGA封装,400个引脚,引脚间距为0.8mm。再次说明一下BGA管脚,当我们使用BGA封装的芯片以后,引脚名称变为由\ **字母+数字**\ 的形式,比如E3,G3等等,因此我们在看原理图的时候,看到的\ **字母+数字**\ 这种形式的,就是代表了BGA的引脚。图3.1为开发板所用的XC7Z020芯片实物图。 .. image:: images/media/image9.jpeg :width: 2.45417in :height: 2.33681in 图4-2 XC7Z020芯片实物 JTAG接口 -------- 首先我们来说AX7020开发板的JTAG调试接口, 在电路板上已经集成了JTAG的下载调试电路,所以用户无需购买额外的Xilinx下载器。只要一根USB线就能进行ZYNQ的开发和调试了。在AX7020开发板上通过一个FTDI的USB桥接芯片FT232HL实现PC的USB和ZYNQ的JTAG调试信号TCK,TDO,TMS,TDI进行数据通信。图4-3为开发板上JTAG口的原理图部分: .. image:: images/media/image10.png :width: 5.89097in :height: 2.86458in 图4-3 原理图中JTAG接口部分 在AX7020开发板上,JTAG接口的形式是USB接口方式的,用户可以通过我们提供的USB线连接PC和JTAG接口进行ZYNQ的系统调试。 .. image:: images/media/image11.png :width: 5.25833in :height: 3.69861in 图4-4 JTAG接口实物图 FPGA供电系统 ------------ 接下来,我们说一下AX7020的电源设计部分。ZYNQ芯片的电源分PS系统部分和PL逻辑部分,两部分的电源分别是独立工作。PS系统部分的电源和PL逻辑部分的电源都有上电顺序,不正常的上电顺序可能会导致ARM系统和FPGA系统无法正常工作。 PS部分的电源有VCCPINT、VCCPAUX、VCCPLL和PS VCCO。VCCPINT为PS内核供电引脚,接1.0V;VCCPAUX为PS系统辅助供电引脚,接1.8V;VCCPLL为PS的内部时钟PLL的电源供电引脚,也接1.8V;PS VCCO为BANK的电压,包含VCCO_MIO0,VCCO_MIO1和VCCO_DDR,根据连接的外设不同,连接的电源电源也会不同,在AX7020开发板上,VCC_MIO0连接3.3V, VCCO_MIO1连接1.8V,VCCO_DDR连接1.5V。PS系统要求上电顺序分别为先VCCPINT供电,然后VCCPAUX和VCCPLL,最后为PS VCCO。断电的顺序则相反。 PL部分的电源有VCCINT, VCCBRAM, VCCAUX和 VCCO。VCCPINT为FPGA内核供电引脚,接1.0V;VCCBRAM为FPGA Block RAM的供电引脚;接1.0V;VCCAUX为FPGA辅助供电引脚, 接1.8V;VCCO为PL的各个BANK的电压,包含BANK13,BANK34,BANK35,在AX7020开发板上,BANK的电压连接3.3V。PL系统要求上电顺序分别为先VCCINT供电,再是VCCBRAM, 然后是VCCAUX,最后为VCCO。如果VCCINT和VCCBRAM的电压一样,可以同时上电。断电的顺序则相反。 ZYNQ启动配置 ------------ AX7020开发平台支持三种启动模式。这三种启动模式分别是JTAG调试模式,QSPI FLASH和SD卡启动模式。ZYNQ702芯片上电后会检测响应MIO口的电平来决定那种启动模式。用户可以通过核心板上的J13的跳线来选择不同的启动模式。J13启动模式配置如下表4-1所示。 +-------------------------+---------------------+---------------------+ | **J13** | **跳帽位置** | **启动模式** | +-------------------------+---------------------+---------------------+ | |image3| | 连接左边两个引脚 | SD Card | +-------------------------+---------------------+---------------------+ | | 连接中间两个引脚 | QSPI FLASH | +-------------------------+---------------------+---------------------+ | | 连接右边边两个引脚 | JTAG | +-------------------------+---------------------+---------------------+ 表4-1 J13启动模式配置 时钟配置 ======== AX7020开发板上分别为PS系统和PL逻辑部分提供了有源时钟,是PS系统和PL逻辑可以单独工作。 5.1 PS系统时钟源 ---------------- ZYNQ芯片通过开发板上的X1晶振为PS部分提供33.333MHz的时钟输入。时钟的输入连接到ZYNQ芯片的BANK500的PS_CLK_500的管脚上。其原理图如图5-1所示: .. image:: images/media/image13.png :width: 5.96319in :height: 1.35278in 图5-1 PS部分的有源晶振 图5-2为有源晶振实物图 .. image:: images/media/image14.png :width: 3.34306in :height: 2.125in 图5-2 33.333Mhz有源晶振实物图 **时钟引脚分配:** +-----------------------------------+-----------------------------------+ | **信号名称** | **ZYNQ引脚** | +-----------------------------------+-----------------------------------+ | **PS_CLK_500** | **E7** | +-----------------------------------+-----------------------------------+ 5.2 PL系统时钟源 ---------------- AX7020开发板上提供了单端50MHz的PL系统时钟源,3.3V供电。晶振输出连接到FPGA的全局时钟(MRCC),这个GCLK可以用来驱动FPGA内的用户逻辑电路。该时钟源的原理图如图5-3所示 .. image:: images/media/image15.png :width: 5.05208in :height: 1.5625in 图 5-3 PL系统时钟源 图5-4为有源晶振50MHz的实物图 .. image:: images/media/image16.png :width: 2.81181in :height: 1.85417in 图5-4 50Mhz有源晶振实物图 **PL时钟引脚分配:** +-----------------------------------+-----------------------------------+ | **信号名称** | **ZYNQ引脚** | +-----------------------------------+-----------------------------------+ | **PL_GCLK** | **U18** | +-----------------------------------+-----------------------------------+ PS端的外设 ========== 因为ZYNQ是由ARM系统PS部分和FPGA逻辑PL部分组成,开发板上有些外设是连接到PS的IO上,有些外设是连接到开发板的PL的IO上。首先我们先对PS部分连接的外设做介绍。 6.1 QSPI Flash -------------- 开发板配有一片256Mbit大小的Quad-SPI FLASH芯片,型号为W25Q256,它使用3.3V CMOS电压标准。由于QSPI FLASH的非易失特性,在使用中, 它可以作为系统的启动设备来存储系统的启动镜像。这些镜像主要包括FPGA的bit文件、ARM的应用程序代码以及其它的用户数据文件。QSPI FLASH的具体型号和相关参数见表6-1。 +--------------+--------------------+------------------+--------------+ | **位号** | **芯片类型** | **容量** | **厂家** | +--------------+--------------------+------------------+--------------+ | U15 | W25Q256 | 32M Byte | Winbond | +--------------+--------------------+------------------+--------------+ 表6-1 QSPI Flash的型号和参数 QSPI FLASH连接到ZYNQ芯片的PS部分BANK500的GPIO口上,在系统设计中需要配置这些PS端的GPIO口功能为QSPI FLASH接口。为图6-1为QSPI Flash在硬件连接示意图。 .. image:: images/media/image17.png :width: 4.92361in :height: 3.60556in 图6-1 QSPI Flash连接示意图 **配置芯片引脚分配:** +-----------------------------+------------------+---------------------+ | **信号名称** | **ZYNQ引脚名** | **ZYNQ引脚号** | +-----------------------------+------------------+---------------------+ | **QSPI_CLK** | PS_MIO6_500 | A5 | +-----------------------------+------------------+---------------------+ | **QSPI_CS** | PS_MIO1_500 | A7 | +-----------------------------+------------------+---------------------+ | **QSPI_D0** | PS_MIO2_500 | B8 | +-----------------------------+------------------+---------------------+ | **QSPI_D1** | PS_MIO3_500 | D6 | +-----------------------------+------------------+---------------------+ | **QSPI_D2** | PS_MIO4_500 | B7 | +-----------------------------+------------------+---------------------+ | **QSPI_D3** | PS_MIO5_500 | A6 | +-----------------------------+------------------+---------------------+ 6.2 DDR3 DRAM ------------- AX7020开发板上配有两个SK hynix(海力士)的4Gbit(512MB)的DDR3芯片(共计8Gbit),型号为H5TQ4G63AFR-PBC(兼容MT41J256M16RE-125)。DDR的总线宽度共为32bit。DDR3 SDRAM的最高运行速度可达533MHz(数据速率1066Mbps)。该DDR3存储系统直接连接到了ZYNQ处理系统(PS)的BANK 502的存储器接口上。DDR3 SDRAM的具体配置如下表6-1所示。 表6-1 DDR3 SDRAM配置 +--------------+--------------------+------------------+--------------+ | **位号** | **芯片类型** | **容量** | **厂家** | +--------------+--------------------+------------------+--------------+ | U8,U9 | H5TQ4G63AFR-PBC | 256M x 16bit | micron | +--------------+--------------------+------------------+--------------+ DDR3的硬件设计需要严格考虑信号完整性,我们在电路设计和PCB设计的时候已经充分考虑了匹配电阻/终端电阻,走线阻抗控制,走线等长控制, 保证DDR3的高速稳定的工作。 DDR3 DRAM的硬件连接示意图如图6-2所示: .. image:: images/media/image18.png :width: 6.25208in :height: 5.16111in 图6-2 DDR3 DRAM原理图部分 图6-3为DDR3 DRAM实物图 .. image:: images/media/image19.png :width: 4.20764in :height: 5.05139in 图6-3 DDR3 DRAM实物图 **DDR3 DRAM引脚分配:** +-----------------------+---------------------+------------------------+ | **信号名称** | **ZYNQ引脚名** | **ZYNQ引脚号** | +-----------------------+---------------------+------------------------+ | **DDR3_DQS0_P** | PS_DDR_DQS_P0_502 | C2 | +-----------------------+---------------------+------------------------+ | **DDR3_DQS0_N** | PS_DDR_DQS_N0_502 | B2 | +-----------------------+---------------------+------------------------+ | **DDR3_DQS1_P** | PS_DDR_DQS_P1_502 | G2 | +-----------------------+---------------------+------------------------+ | **DDR3_DQS1_N** | PS_DDR_DQS_N1_502 | F2 | +-----------------------+---------------------+------------------------+ | **DDR3_DQS2_P** | PS_DDR_DQS_P2_502 | R2 | +-----------------------+---------------------+------------------------+ | **DDR3_DQS2_N** | PS_DDR_DQS_N2_502 | T2 | +-----------------------+---------------------+------------------------+ | **DDR3_DQS3_P** | PS_DDR_DQS_P3_502 | W5 | +-----------------------+---------------------+------------------------+ | **DDR3_DQS4_N** | PS_DDR_DQS_N3_502 | W4 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ[0]** | PS_DDR_DQ0_502 | C3 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [1]** | PS_DDR_DQ1_502 | B3 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [2]** | PS_DDR_DQ2_502 | A2 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [3]** | PS_DDR_DQ3_502 | A4 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [4]** | PS_DDR_DQ4_502 | D3 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [5]** | PS_DDR_DQ5_502 | D1 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [6]** | PS_DDR_DQ6_502 | C1 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [7]** | PS_DDR_DQ7_502 | E1 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [8]** | PS_DDR_DQ8_502 | E2 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [9]** | PS_DDR_DQ9_502 | E3 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [10]** | PS_DDR_DQ10_502 | G3 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [11]** | PS_DDR_DQ11_502 | H3 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [12]** | PS_DDR_DQ12_502 | J3 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [13]** | PS_DDR_DQ13_502 | H2 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [14]** | PS_DDR_DQ14_502 | H1 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [15]** | PS_DDR_DQ15_502 | J1 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [16]** | PS_DDR_DQ16_502 | P1 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [17]** | PS_DDR_DQ17_502 | P3 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [18]** | PS_DDR_DQ18_502 | R3 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [19]** | PS_DDR_DQ19_502 | R1 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [20]** | PS_DDR_DQ20_502 | T4 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [21]** | PS_DDR_DQ21_502 | U4 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [22]** | PS_DDR_DQ22_502 | U2 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [23]** | PS_DDR_DQ23_502 | U3 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [24]** | PS_DDR_DQ24_502 | V1 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [25]** | PS_DDR_DQ25_502 | Y3 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [26]** | PS_DDR_DQ26_502 | W1 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [27]** | PS_DDR_DQ27_502 | Y4 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [28]** | PS_DDR_DQ28_502 | Y2 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [29]** | PS_DDR_DQ29_502 | W3 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [30]** | PS_DDR_DQ30_502 | V2 | +-----------------------+---------------------+------------------------+ | **DDR3_DQ [31]** | PS_DDR_DQ31_502 | V3 | +-----------------------+---------------------+------------------------+ | **DDR3_DM0** | PS_DDR_DM0_502 | A1 | +-----------------------+---------------------+------------------------+ | **DDR3_DM1** | PS_DDR_DM1_502 | F1 | +-----------------------+---------------------+------------------------+ | **DDR3_DM2** | PS_DDR_DM2_502 | T1 | +-----------------------+---------------------+------------------------+ | **DDR3_DM3** | PS_DDR_DM3_502 | Y1 | +-----------------------+---------------------+------------------------+ | **DDR3_A[0]** | PS_DDR_A0_502 | N2 | +-----------------------+---------------------+------------------------+ | **DDR3_A[1]** | PS_DDR_A1_502 | K2 | +-----------------------+---------------------+------------------------+ | **DDR3_A[2]** | PS_DDR_A2_502 | M3 | +-----------------------+---------------------+------------------------+ | **DDR3_A[3]** | PS_DDR_A3_502 | K3 | +-----------------------+---------------------+------------------------+ | **DDR3_A[4]** | PS_DDR_A4_502 | M4 | +-----------------------+---------------------+------------------------+ | **DDR3_A[5]** | PS_DDR_A5_502 | L1 | +-----------------------+---------------------+------------------------+ | **DDR3_A[6]** | PS_DDR_A6_502 | L4 | +-----------------------+---------------------+------------------------+ | **DDR3_A[7]** | PS_DDR_A7_502 | K4 | +-----------------------+---------------------+------------------------+ | **DDR3_A[8]** | PS_DDR_A8_502 | K1 | +-----------------------+---------------------+------------------------+ | **DDR3_A[9]** | PS_DDR_A9_502 | J4 | +-----------------------+---------------------+------------------------+ | **DDR3_A[10]** | PS_DDR_A10_502 | F5 | +-----------------------+---------------------+------------------------+ | **DDR3_A[11]** | PS_DDR_A11_502 | G4 | +-----------------------+---------------------+------------------------+ | **DDR3_A[12]** | PS_DDR_A12_502 | E4 | +-----------------------+---------------------+------------------------+ | **DDR3_A[13]** | PS_DDR_A13_502 | D4 | +-----------------------+---------------------+------------------------+ | **DDR3_A[14]** | PS_DDR_A14_502 | F4 | +-----------------------+---------------------+------------------------+ | **DDR3_BA[0]** | PS_DDR_BA0_502 | L5 | +-----------------------+---------------------+------------------------+ | **DDR3_BA[1]** | PS_DDR_BA1_502 | R4 | +-----------------------+---------------------+------------------------+ | **DDR3_BA[2]** | PS_DDR_BA2_502 | J5 | +-----------------------+---------------------+------------------------+ | **DDR3_S0** | PS_DDR_CS_B_502 | N1 | +-----------------------+---------------------+------------------------+ | **DDR3_RAS** | PS_DDR_RAS_B_502 | P4 | +-----------------------+---------------------+------------------------+ | **DDR3_CAS** | PS_DDR_CAS_B_502 | P5 | +-----------------------+---------------------+------------------------+ | **DDR3_WE** | PS_DDR_WE_B_502 | M5 | +-----------------------+---------------------+------------------------+ | **DDR3_ODT** | PS_DDR_ODT_502 | N5 | +-----------------------+---------------------+------------------------+ | **DDR3_RESET** | PS_DDR_DRST_B_502 | B4 | +-----------------------+---------------------+------------------------+ | **DDR3_CLK_P** | PS_DDR_CKP_502 | L2 | +-----------------------+---------------------+------------------------+ | **DDR3_CLK_N** | PS_DDR_CKN_502 | M2 | +-----------------------+---------------------+------------------------+ | **DDR3_CKE** | PS_DDR_CKE_502 | N3 | +-----------------------+---------------------+------------------------+ 6.3 千兆以太网接口 ------------------ AX7020开发板上通过Realtek RTL8211E-VL以太网PHY芯片用户提供网络通信服务。以太网PHY芯片是连接到ZYNQ的PS端BANK501的GPIO接口上。RTL8211E-VL芯片支持10/100/1000 Mbps网络传输速率,通过RGMII接口跟Zynq7000 PS 系统的MAC层进行数据通信。RTL8211E-VL支持MDI/MDX自适应,各种速度自适应,Master/Slave自适应,支持MDIO总线进行PHY的寄存器管理。 RTL8211E-VL上电会检测一些特定的IO的电平状态,从而确定自己的工作模式。表6-2 描述了GPHY芯片上电之后的默认设定信息。 +-----------------+--------------------------+-------------------------+ | **配置Pin脚** | **说明** | **配置值** | +-----------------+--------------------------+-------------------------+ | **PHYAD[2:0]** | MDIO/MDC 模式的PHY地址 | PHY Address 为 001 | +-----------------+--------------------------+-------------------------+ | **SELRGV** | RGMII 1.8V或1.5V电平选择 | 1.8V | +-----------------+--------------------------+-------------------------+ | **AN[1:0]** | 自协商配置 | (10/100/1000M)自适应 | +-----------------+--------------------------+-------------------------+ | **RX Delay** | RX时钟2ns延时 | 延时 | +-----------------+--------------------------+-------------------------+ | **TX Delay** | TX时钟2ns延时 | 延时 | +-----------------+--------------------------+-------------------------+ 表6-2 PHY芯片默认配置值 当网络连接到千兆以太网时,FPGA和PHY芯片RTL8211E-VL的数据传输时通过RGMII总线通信,传输时钟为125Mhz,数据在时钟的上升沿和下降样采样。 当网络连接到百兆以太网时,FPGA和PHY芯片RTL8211E-VL的数据传输时通过RMII总线通信,传输时钟为25Mhz。数据在时钟的上升沿和下降样采样。 图6-4为ZYNQ与以太网PHY芯片连接示意图: |image4|               图6-4 FPGA与PHY连接示意图 图6-5为以太网PHY芯片的实物图 .. image:: images/media/image21.png :width: 4.40486in :height: 3.63611in 图6-5 以太网PHY芯片实物图 **以太网引脚分配如下:** +-----------------+----------------+-----------------+-----------------+ | **信号名称** | **ZYNQ引脚名** | **ZYNQ引脚号** | **备注** | +-----------------+----------------+-----------------+-----------------+ | **ETH_GCLK** | PS_MIO16_501 | A19 | RGMII 发送时钟 | +-----------------+----------------+-----------------+-----------------+ | **ETH_TXD0** | PS_MIO17_501 | E14 | 发送数据bit0 | +-----------------+----------------+-----------------+-----------------+ | **ETH_TXD1** | PS_MIO18_501 | B18 | 发送数据bit1 | +-----------------+----------------+-----------------+-----------------+ | **ETH_TXD2** | PS_MIO19_501 | D10 | 发送数据bit2 | +-----------------+----------------+-----------------+-----------------+ | **ETH_TXD3** | PS_MIO20_501 | A17 | 发送数据bit3 | +-----------------+----------------+-----------------+-----------------+ | **ETH_TXCTL** | PS_MIO21_501 | F14 | 发送使能信号 | +-----------------+----------------+-----------------+-----------------+ | **ETH_RXCK** | PS_MIO22_501 | B17 | RGMII接收时钟 | +-----------------+----------------+-----------------+-----------------+ | **ETH_RXD0** | PS_MIO23_501 | D11 | 接收数据Bit0 | +-----------------+----------------+-----------------+-----------------+ | **ETH_RXD1** | PS_MIO24_501 | A16 | 接收数据Bit1 | +-----------------+----------------+-----------------+-----------------+ | **ETH_RXD2** | PS_MIO25_501 | F15 | 接收数据Bit2 | +-----------------+----------------+-----------------+-----------------+ | **ETH_RXD3** | PS_MIO26_501 | A15 | 接收数据Bit3 | +-----------------+----------------+-----------------+-----------------+ | **ETH_RXCTL** | PS_MIO27_501 | D13 | 接 | | | | | 收数据有效信号 | +-----------------+----------------+-----------------+-----------------+ | **ETH_MDC** | PS_MIO52_501 | C10 | MDIO管理时钟 | +-----------------+----------------+-----------------+-----------------+ | **ETH_MDIO** | PS_MIO53_501 | C11 | MDIO管理数据 | +-----------------+----------------+-----------------+-----------------+ 6.4 USB2.0 ---------- AX7020使用的USB2.0收发器是一个1.8V的,高速的支持ULPI标准接口的USB3320C-EZK。ZYNQ的USB总线接口和USB3320C-EZK收发器相连接,实现高速的USB2.0 Host模式和Slave模式的数据通信。USB3320C的USB的数据和控制信号连接到ZYNQ芯片PS端的BANK501的IO口上,一个24MHz的晶振为USB3320C提供系统时钟。 开发板上为用户提供了两个USB接口,一个是Host USB口,一个是Slave USB口。分别为扁型USB接口(USB Type A) 和微型USB接口(Micro USB), 方便用户连接不同的USB外设。用户可以通过开发板上的J5,J6的跳线实现Host和Slave的切换。表6-3为模式切换说明: 表6-3 USB接口模式切换说明 +------------------+-------------------+------------------------------+ | **J5, J6状态** | **USB模式** | **说明** | +------------------+-------------------+------------------------------+ | J5和J6安装跳线帽 | HOST 模式 | 开发板作为主设备,USB口 | | | | 连接鼠标,键盘,USB等从外设 | +------------------+-------------------+------------------------------+ | J5 | Slave 模式 | 开发 | | 和J6不安装跳线帽 | | 板作为从设备,USB口连接电脑 | +------------------+-------------------+------------------------------+ ZYNQ处理器和USB3320C-EZK芯片连接的示意图如6-6所示: .. image:: images/media/image22.png :width: 6.02153in :height: 2.56181in 图6-6 Zynq7000和USB芯片间连接示意图 图6-7为USB2.0部分的实物图,U11为USB3320C,J3为Host USB接口, J4为Slave USB接口。跳线帽J5和J6用于Host和Slave模式的选择。 .. image:: images/media/image23.png :width: 4.18333in :height: 3.37917in 图6-7 USB2.0部分的实物图 **USB2.0引脚分配:** +---------------+--------------+------------+-------------------------+ | **信号名称** | **ZY | **ZY | **备注** | | | NQ引脚名** | NQ引脚号** | | +---------------+--------------+------------+-------------------------+ | OTG_DATA4 | PS_MIO28_501 | C16 | USB数据Bit4 | +---------------+--------------+------------+-------------------------+ | OTG_DIR | PS_MIO29_501 | C13 | USB数据方向信号 | +---------------+--------------+------------+-------------------------+ | OTG_STP | PS_MIO30_501 | C15 | USB停止信号 | +---------------+--------------+------------+-------------------------+ | OTG_NXT | PS_MIO31_501 | E16 | USB下一数据信号 | +---------------+--------------+------------+-------------------------+ | OTG_DATA0 | PS_MIO32_501 | A14 | USB数据Bit0 | +---------------+--------------+------------+-------------------------+ | OTG_DATA1 | PS_MIO33_501 | D15 | USB数据Bit1 | +---------------+--------------+------------+-------------------------+ | OTG_DATA2 | PS_MIO34_501 | A12 | USB数据Bit2 | +---------------+--------------+------------+-------------------------+ | OTG_DATA3 | PS_MIO35_501 | F12 | USB数据Bit3 | +---------------+--------------+------------+-------------------------+ | OTG_CLK | PS_MIO36_501 | A11 | USB时钟信号 | +---------------+--------------+------------+-------------------------+ | OTG_DATA5 | PS_MIO37_501 | A10 | USB数据Bit5 | +---------------+--------------+------------+-------------------------+ | OTG_DATA6 | PS_MIO38_501 | E13 | USB数据Bit6 | +---------------+--------------+------------+-------------------------+ | OTG_DATA7 | PS_MIO39_501 | C18 | USB数据Bit7 | +---------------+--------------+------------+-------------------------+ | OTG_RESETN | PS_MIO46_501 | D16 | USB复位信号 | +---------------+--------------+------------+-------------------------+ 6.5 USB转串口 ------------- AX7020开发板采用Silicon Labs CP2102GM的USB转UART芯片, USB接口采用Micro USB接口,用户可以用一根Micro USB线连接到PC上进行串口通信。 UART的TX/RX信号与ZYNQ EPP 的PS BANK501的信号相连,因为该BANK的VCCMIO设置为1.8V,但CP2102GM的数据电平为3.3V, 我们这里通过TXS0102DCUR电平转换芯片来连接。CP2102GM和ZYNQ连接的示意图如图6-8所示: .. image:: images/media/image24.png :width: 6.41111in :height: 2.08681in 图6-8 CP2102GM连接示意图 图6-9为USB转串口的实物图 .. image:: images/media/image25.png :width: 4.85833in :height: 3.21458in 图6-9 USB转串口实物图 **ZYNQ串口引脚分配:** +---------------+--------------+------------+-------------------------+ | **信号名称** | **ZY | **ZY | **备注** | | | NQ引脚名** | NQ引脚号** | | +---------------+--------------+------------+-------------------------+ | UART_TX | PS_MIO48_501 | B12 | Uart数据输出 | +---------------+--------------+------------+-------------------------+ | UART_RX | PS_MIO49_501 | C12 | Uart数据输入 | +---------------+--------------+------------+-------------------------+ Silicon Labs为主机PC提供了虚拟COM端口(VCP)驱动程序。这些驱动程序允许CP2102GM USB-UART桥接设备在通信应用软件(例如,TeraTerm或超级终端)显示为一个COM端口。VCP设备驱动程序必须在PC主机与AX7020开发板板建立通信前进行安装。 6.6 SD卡槽 ---------- AX7020开发板包含了一个Micro型的SD卡接口,以提供用户访问SD卡存储器,用于存储ZYNQ芯片的BOOT程序,Linux操作系统内核, 文件系统以及其它的用户数据文件。 SDIO信号与ZYNQ的PS BANK501的IO信号相连,因为该BANK的VCCMIO设置为1.8V,但SD卡的数据电平为3.3V, 我们这里通过TXS02612电平转换器来连接。Zynq7000 PS和SD卡连接器的原理图如图6-10所示。 .. image:: images/media/image26.png :width: 6.36667in :height: 2.88611in 图6-10 SD卡连接示意图 SD卡槽在开发板的背面,图6-11 SD卡槽实物图 .. image:: images/media/image27.png :width: 3.28125in :height: 2.58403in 图6-11 SD卡槽实物图 **SD卡槽引脚分配** +---------------+--------------+------------+-------------------------+ | **信号名称** | **ZY | **ZY | **备注** | | | NQ引脚名** | NQ引脚号** | | +---------------+--------------+------------+-------------------------+ | SD_CLK | PS_MIO40 | D14 | SD时钟信号 | +---------------+--------------+------------+-------------------------+ | SD_CMD | PS_MIO41 | C17 | SD命令信号 | +---------------+--------------+------------+-------------------------+ | SD_D0 | PS_MIO42 | E12 | SD数据Data0 | +---------------+--------------+------------+-------------------------+ | SD_D1 | PS_MIO43 | A9 | SD数据Data1 | +---------------+--------------+------------+-------------------------+ | SD_D2 | PS_MIO44 | F13 | SD数据Data2 | +---------------+--------------+------------+-------------------------+ | SD_D3 | PS_MIO45 | B15 | SD数据Data3 | +---------------+--------------+------------+-------------------------+ | SD_CD | PS_MIO47 | B14 | SD卡插入信号 | +---------------+--------------+------------+-------------------------+ 6.7 PS PMOD连接器 ----------------- AX7020开发板预留了一个12针2.54mm间距的PMOD接口(J12)用于连接PS BANK500的IO和外部模块或电路。因为BANK500的IO是3.3V标准的,所以连接的外部设备和电路的信号也需要3.3V电平标准。PMOD连接器的原理图如图6-12所示 .. image:: images/media/image28.png :width: 6.09514in :height: 1.68125in 图6-12 PMOD连接器原理图 图6-13 为PS PMOD连接器的实物图 .. image:: images/media/image29.png :width: 4.37778in :height: 2.9375in 图6-13 PS PMOD连接器的实物图 **PS PMOD连接器的引脚分配** +---------------+----------------+-----------------+------------------+ | **PMOD 管脚** | **信号名称** | **ZYNQ引脚名** | **ZYNQ引脚号** | +---------------+----------------+-----------------+------------------+ | PIN1 | PMOD_IO0 | PS_MIO11_500 | C6 | +---------------+----------------+-----------------+------------------+ | PIN2 | PMOD_IO2 | PS_MIO9_500 | B5 | +---------------+----------------+-----------------+------------------+ | PIN3 | PMOD_IO3 | PS_MIO15_500 | C8 | +---------------+----------------+-----------------+------------------+ | PIN4 | PMOD_IO4 | PS_MIO7_500 | D8 | +---------------+----------------+-----------------+------------------+ | PIN5 | GND | - | - | +---------------+----------------+-----------------+------------------+ | PIN6 | +3.3V | - | - | +---------------+----------------+-----------------+------------------+ | PIN7 | PMOD_IO1 | PS_MIO10_500 | E9 | +---------------+----------------+-----------------+------------------+ | PIN8 | PMOD_IO6 | PS_MIO8_500 | D5 | +---------------+----------------+-----------------+------------------+ | PIN9 | PMOD_IO7 | PS_MIO14_500 | C5 | +---------------+----------------+-----------------+------------------+ | PIN10 | PMOD_IO5 | PS_MIO12_500 | D9 | +---------------+----------------+-----------------+------------------+ | PIN11 | GND | - | - | +---------------+----------------+-----------------+------------------+ | PIN12 | +3.3V | - | - | +---------------+----------------+-----------------+------------------+ 6.8用户LED ---------- AX7020开发板上,PS部分的BANK500 IO上连接了2个LED发光二极管,用户可以使用这两个LED灯来调试程序。当BANK500 IO电压为高时,LED灯熄灭,当BANK500 IO电压为低时,LED会被点亮。ZYNQ BANK500 IO和LED灯连接的示意图如图6-14所示: .. image:: images/media/image30.png :width: 4.30139in :height: 2.35417in 图6-14 Zynq-7000和LED灯连接示意图 图6-15 为PS的LED灯实物图 .. image:: images/media/image31.png :width: 2.08333in :height: 0.97917in 图6-15 PS的LED灯实物图 **PS LED灯的引脚分配** +---------------+--------------+----------------+----------------------+ | **信号名称** | **ZY | **ZYNQ引脚号** | **备注** | | | NQ引脚名** | | | +---------------+--------------+----------------+----------------------+ | MIO0_LED | PS_MIO0_500 | E6 | PS LED1灯 | +---------------+--------------+----------------+----------------------+ | MIO13_LED | PS_MIO13_500 | E8 | PS LED2灯 | +---------------+--------------+----------------+----------------------+ 6.9 用户按键 ------------ AX7020开发板上,PS部分的BANK501 IO上连接了2个用户按键,用户可以使用这两个用户按键来测试输入信号和中断触发。设计中按键按下,输入到ZYNQ BANK501 IO上的信号电压为低,没有按下时,信号为高。 ZYNQ BANK501 IO和按键连接的示意图如图6-16所示: .. image:: images/media/image32.png :width: 5.33125in :height: 2.12222in 图6-16 Zynq-7000和按键连接示意图 图6-17 为PS的按键实物图 .. image:: images/media/image33.png :width: 2.42708in :height: 1.64583in 图6-17 PS的按键实物图 **PS LED灯的引脚分配** +---------------+--------------+------------+-------------------------+ | **信号名称** | **ZY | **ZY | **备注** | | | NQ引脚名** | NQ引脚号** | | +---------------+--------------+------------+-------------------------+ | MIO_KEY1 | PS_MIO50_501 | B13 | PS用户按键KEY1 | +---------------+--------------+------------+-------------------------+ | MIO_KEY2 | PS_MIO51_501 | B9 | PS用户按键KEY2 | +---------------+--------------+------------+-------------------------+ PL端的外设 ========== 下面我们再对PL部分(FPGA逻辑部分)连接的外设做一下介绍。 7.1 HDMI 接口 ------------- HDMI,全称为高清晰度多媒体视频输出接口。AX7020开发板上通过FPGA的差分IO直接连接到HDMI接口的差分信号和时钟,在FPGA内部实现HMDI信号的差分转并行再进行编解码,实现DMI数字视频输入和输出的传输解决方案,最高支持1080P@60Hz的输入和输出的功能。 HDMI的信号连接到ZYNQ的PL部分的BANK34上,图6-1-1为HDMI设计的原理图,当开发板作为HDMI显示设备时(HDMI IN),HDMI信号作为输入,HPD(hot plug detect)信号作为输出。当开发板作为HDMI主设备(HDMI OUT)时,则相反。 .. image:: images/media/image34.png :width: 6.54444in :height: 2.43819in 图7-1为HDMI设计的原理图 开发板在作为HDMI主设备(HDMI OUT)时,需要提供给HDMI显示设备一个+5V的电源。电源输出控制电路如图7-2所示 .. image:: images/media/image35.png :width: 5.84306in :height: 1.63194in 图7-2 HDMI 5V输出电路 另外HMDI主设备会通过IIC总线读取HDMI显示设备的EDID设备信息。FPGA的管脚电平是3.3V, 但HDMI的电平是+5V, 这里我们需要电平转换芯片GTL2002D来连接。IIC的转换电路如图7-3所示 .. image:: images/media/image36.png :width: 5.81111in :height: 1.55347in 图7-3 GTL2002D电平转换电路 图7-4 为HDMI接口的实物图 .. image:: images/media/image37.png :width: 3.70764in :height: 2.625in 图7-4 HDMI接口的实物图 **HDMI接口的引脚分配** +--------------+-------------------+-----------+----------------------+ | **信号名称** | **ZYNQ引脚名** | **ZYN | **备注** | | | | Q引脚号** | | +--------------+-------------------+-----------+----------------------+ | HDMI_CLK_P | I | N18 | HDMI时钟信号正 | | | O_L13P_T2_MRCC_34 | | | +--------------+-------------------+-----------+----------------------+ | HDMI_CLK_N | I | P19 | HDMI时钟信号负 | | | O_L13N_T2_MRCC_34 | | | +--------------+-------------------+-----------+----------------------+ | HDMI_D0_P | IO_L16P_T2_34 | V20 | HDMI数据0正 | +--------------+-------------------+-----------+----------------------+ | HDMI_D0_N | IO_L16N_T2_34 | W20 | HDMI数据0负 | +--------------+-------------------+-----------+----------------------+ | HDMI_D1_P | IO_L15P_T2_DQS_34 | T20 | HDMI数据1正 | +--------------+-------------------+-----------+----------------------+ | HDMI_D1_N | IO_L15N_T2_DQS_34 | U20 | HDMI数据1负 | +--------------+-------------------+-----------+----------------------+ | HDMI_D2_P | I | N20 | HDMI数据2正 | | | O_L14P_T2_SRCC_34 | | | +--------------+-------------------+-----------+----------------------+ | HDMI_D2_N | I | P20 | HDMI数据2负 | | | O_L14N_T2_SRCC_34 | | | +--------------+-------------------+-----------+----------------------+ | HDMI_SCL | IO_L20N_T3_34 | R18 | HDMI IIC时钟 | +--------------+-------------------+-----------+----------------------+ | HDMI_SDA | IO_L19P_T2_34 | R16 | HDMI IIC数据 | +--------------+-------------------+-----------+----------------------+ | HDMI_CEC | IO_L17P_T2_34 | Y18 | HDMI遥控器信号 | +--------------+-------------------+-----------+----------------------+ | HDMI_HPD | IO_L17N_T2_34 | Y19 | HDMI热插拔检测信号 | +--------------+-------------------+-----------+----------------------+ | HDMI_OUT_EN | IO_L18P_T2_34 | V16 | HDMI电源输出控制 | +--------------+-------------------+-----------+----------------------+ 7.2 EEPROM 24LC04 ----------------- AX7020开发板板载了一片EEPROM,型号为24LC04,容量为:4Kbit(2*256*8bit),由2个256byte的block组成,通过IIC总线进行通信。板载EEPROM就是为了学习IIC总线的通信方式。EEPROM的I2C信号连接的ZYNQ PL端的BANK34 IO口上。图7-5为EEPROM的原理图 .. image:: images/media/image38.png :width: 5.85486in :height: 3.55139in 图7-5 EEPROM原理图部分 图7-6为EEPROM实物图 .. image:: images/media/image39.png :width: 2.40625in :height: 1.61458in 图7-6 EEPROM实物图 **EEPROM引脚分配:** +----------------+-------------------+-----------+--------------------+ | **信号名称** | **ZYNQ引脚名** | **ZYN | **备注** | | | | Q引脚号** | | +----------------+-------------------+-----------+--------------------+ | EEPROM_I2C_SCL | IO_25_34 | T19 | IIC时钟信号 | +----------------+-------------------+-----------+--------------------+ | EEPROM_I2C_SDA | IO_L12N_T1_34 | U19 | IIC数据信号 | +----------------+-------------------+-----------+--------------------+ 7.3 实时时钟 DS1302 ------------------- 开发板板载了一片实时时钟RTC芯片,型号DS1302,他的功能是提供到2099年内的日历功能,年月日时分秒还有星期。如果系统中需要时间的话,那么RTC就需要涉及到产品中。他外部需要接一个32.768KHz的无源时钟,提供精确的时钟源给时钟芯片,这样才能让RTC可以准确的提供时钟信息给产品。同时为了产品掉电以后,实时时钟还可以正常运行,一般需要另外配一个电池给时钟芯片供电,图6-3-1中为BT1为电池座,我们将纽扣电池(型号CR1220,电压为3V)放入以后,当系统掉电池,纽扣电池还可以给DS1302供电,这样,不管产品是否供电,DS1302都会正常运行,不会间断,可以提供持续不断的时间信息。RTC的接口信号也是连接到ZYNQ PL端的BANK34和BANK35 IO口上。图7-7为DS1302原理图 .. image:: images/media/image40.png :width: 5.64028in :height: 2.51667in 图7-7 DS1302原理图 图7-8为DS1302实物图 .. image:: images/media/image41.png :width: 3.725in :height: 3.05903in 图7-8 DS1302实物图 **DS1302接口引脚分配:** +---------------+--------------------+-------------+------------------+ | **信号名称** | **ZYNQ引脚名** | **Z | **备注** | | | | YNQ引脚号** | | +---------------+--------------------+-------------+------------------+ | **RTC | **IO_0_34** | R19 | RTC的时钟信号 | | \_SCLK** | | | | +---------------+--------------------+-------------+------------------+ | **RTC_RESET** | **IO | L15 | RTC的复位信号 | | | _L22N_T3_AD7N_35** | | | +---------------+--------------------+-------------+------------------+ | **RTC | **IO | L14 | RTC的数据信号 | | \_DATA** | _L22P_T3_AD7P_35** | | | +---------------+--------------------+-------------+------------------+ 7.4 扩展口J10 ------------- 扩展口J10为40管脚的2.54mm的双排连接器,为用户扩展更多的外设和接口,目前ALINX黑金提供的模块有:\ **ADDA模块,液晶屏模块,千兆以太网模块,音频输入输出模块,矩阵键盘模块,500W双目视觉摄像头模块**\ 。扩展口上包含5V电源1路,3.3V电源2路,地3路,IO口34路。IO口的信号连接到ZYNQ PL的BANK34和BANK35上,电平默认为3.3V,扩展口J10的部分IO可以通过更换开发板上电源芯片(SPX3819M5-3-3)改变IO的电平。\ **切勿直接跟5V设备直接连接,以免烧坏FPGA。如果要接5V设备,需要接电平转换芯片。** 在扩展口和FPGA连接之间串联了33欧姆的排阻,用于保护FPGA以免外界电压或电流过高造成损坏。PCB设计上P和N的走线使用差分走线,控制差分阻抗为100欧姆。扩展口(J10)的电路如图7-9所示: .. image:: images/media/image42.png :width: 3.99514in :height: 3.13333in 图7-9 J10扩展口原理图 图7-10为J10扩展口实物图,扩展口的Pin1,Pin2和Pin39,Pin40已经在板上标示出。 .. image:: images/media/image43.png :width: 5.01458in :height: 1.44236in 图7-10 J10扩展口实物图 **J10扩展口引脚分配** +---------------+----------------+-----------------+------------------+ | **J10管脚** | **信号名称** | **ZYNQ引脚名** | **ZYNQ引脚号** | +---------------+----------------+-----------------+------------------+ | PIN1 | GND | - | - | +---------------+----------------+-----------------+------------------+ | PIN2 | +5V | - | - | +---------------+----------------+-----------------+------------------+ | PIN3 | EX_IO1_1N | IO_L22N_T3_34 | W19 | +---------------+----------------+-----------------+------------------+ | PIN4 | EX_IO1_1P | IO_L22P_T3_34 | W18 | +---------------+----------------+-----------------+------------------+ | PIN5 | EX_IO1_2N | IO_L6N_T0_34 | R14 | +---------------+----------------+-----------------+------------------+ | PIN6 | EX_IO1_2P | IO_L6P_T0_34 | P14 | +---------------+----------------+-----------------+------------------+ | PIN7 | EX_IO1_3N | IO_L7N_T1_34 | Y17 | +---------------+----------------+-----------------+------------------+ | PIN8 | EX_IO1_3P | IO_L7P_T1_34 | Y16 | +---------------+----------------+-----------------+------------------+ | PIN9 | EX_IO1_4N | IO_L10N_T1_34 | W15 | +---------------+----------------+-----------------+------------------+ | PIN10 | EX_IO1_4P | IO_L10P_T1_34 | V15 | +---------------+----------------+-----------------+------------------+ | PIN11 | EX_IO1_5N | IO_L8N_T1_34 | Y14 | +---------------+----------------+-----------------+------------------+ | PIN12 | EX_IO1_5P | IO_L8P_T1_34 | W14 | +---------------+----------------+-----------------+------------------+ | PIN13 | EX_IO1_6N | IO_L23N_T3_34 | P18 | +---------------+----------------+-----------------+------------------+ | PIN14 | EX_IO1_6P | IO_L23P_T3_34 | N17 | +---------------+----------------+-----------------+------------------+ | PIN15 | EX_IO1_7N | IO_L11N_T1_34 | U15 | +---------------+----------------+-----------------+------------------+ | PIN16 | EX_IO1_7P | IO_L11P_T1_34 | U14 | +---------------+----------------+-----------------+------------------+ | PIN17 | EX_IO1_8N | IO_L24N_T3_34 | P16 | +---------------+----------------+-----------------+------------------+ | PIN18 | EX_IO1_8P | IO_L24P_T3_34 | P15 | +---------------+----------------+-----------------+------------------+ | PIN19 | EX_IO1_9N | IO_L9N \_T1_34 | U17 | +---------------+----------------+-----------------+------------------+ | PIN20 | EX_IO1_9P | IO_L9P_T1_34 | T16 | +---------------+----------------+-----------------+------------------+ | PIN21 | EX_IO1_10N | IO_L21_N_T3_34 | V18 | +---------------+----------------+-----------------+------------------+ | PIN22 | EX_IO1_10P | IO_L21_P_T3_34 | V17 | +---------------+----------------+-----------------+------------------+ | PIN23 | EX_IO1_11N | IO_L5N_T0_34 | T15 | +---------------+----------------+-----------------+------------------+ | PIN24 | EX_IO1_11P | IO_L5P_T0_34 | T14 | +---------------+----------------+-----------------+------------------+ | PIN25 | EX_IO1_12N | IO_L3N_T0_34 | V13 | +---------------+----------------+-----------------+------------------+ | PIN26 | EX_IO1_12P | IO_L3P_T0_34 | U13 | +---------------+----------------+-----------------+------------------+ | PIN27 | EX_IO1_13N | IO_L4N_T0_34 | W13 | +---------------+----------------+-----------------+------------------+ | PIN28 | EX_IO1_13P | IO_L4P_T0_34 | V12 | +---------------+----------------+-----------------+------------------+ | PIN29 | EX_IO1_14N | IO_L2N_T0_34 | U12 | +---------------+----------------+-----------------+------------------+ | PIN30 | EX_IO1_14P | IO_L2P_T0_34 | T12 | +---------------+----------------+-----------------+------------------+ | PIN31 | EX_IO1_15N | IO_L1N_T0_34 | T10 | +---------------+----------------+-----------------+------------------+ | PIN32 | EX_IO1_15P | IO_L1P_T0_34 | T11 | +---------------+----------------+-----------------+------------------+ | PIN33 | EX_IO1_16N | IO_L2N_T0_35 | A20 | +---------------+----------------+-----------------+------------------+ | PIN34 | EX_IO1_16P | IO_L2P_T0_35 | B19 | +---------------+----------------+-----------------+------------------+ | PIN35 | EX_IO1_17N | IO_L1N_T0_35 | B20 | +---------------+----------------+-----------------+------------------+ | PIN36 | EX_IO1_17P | IO_L1P_T0_35 | C20 | +---------------+----------------+-----------------+------------------+ | PIN37 | GND | - | - | +---------------+----------------+-----------------+------------------+ | PIN38 | GND | - | - | +---------------+----------------+-----------------+------------------+ | PIN39 | +3.3V | - | - | +---------------+----------------+-----------------+------------------+ | PIN40 | +3.3V | - | - | +---------------+----------------+-----------------+------------------+ 7.5 扩展口J11 ------------- 扩展口J11也为40管脚的2.54mm的双排连接器,为用户扩展更多的外设和接口,目前ALINX黑金提供的模块有:\ **ADDA模块,液晶屏模块,千兆以太网模块,音频输入输出模块,矩阵键盘模块,500W双目视觉摄像头模块**\ 。扩展口上包含5V电源1路,3.3V电源2路,地3路,IO口34路。IO口的信号连接到ZYNQ PL的BANK35上,电平默认为3.3V,扩展口J11的全部IO可以通过更换开发板上电源芯片(SPX3819M5-3-3)改变IO的电平。\ **切勿直接跟5V设备直接连接,以免烧坏FPGA。如果要接5V设备,需要接电平转换芯片。** 在扩展口和FPGA连接之间串联了33欧姆的排阻,用于保护FPGA以免外界电压或电流过高造成损坏,PCB设计上P和N的走线使用差分走线,控制差分阻抗为100欧姆。扩展口(J11)的电路如图7-11所示 .. image:: images/media/image44.png :width: 5.15069in :height: 4.17361in 图7-11 J11扩展口原理图 图7-12为J11扩展口实物图,扩展口的Pin1,Pin2和Pin39,Pin40已经在板上标示出。 .. image:: images/media/image45.png :width: 4.73889in :height: 3.64514in 图7-12 J11扩展口实物图 **J11扩展口引脚分配** +---------------+----------------+-----------------+------------------+ | **J11管脚** | **信号名称** | **ZYNQ引脚名** | **ZYNQ引脚号** | +---------------+----------------+-----------------+------------------+ | PIN1 | GND | - | - | +---------------+----------------+-----------------+------------------+ | PIN2 | +5V | - | - | +---------------+----------------+-----------------+------------------+ | PIN3 | EX_IO2_1N | IO_L6N_T0_35 | F17 | +---------------+----------------+-----------------+------------------+ | PIN4 | EX_IO2_1P | IO_L6P_T0_35 | F16 | +---------------+----------------+-----------------+------------------+ | PIN5 | EX_IO2_2N | IO_L15N_T2_35 | F20 | +---------------+----------------+-----------------+------------------+ | PIN6 | EX_IO2_2P | IO_L15P_T2_35 | F19 | +---------------+----------------+-----------------+------------------+ | PIN7 | EX_IO2_3N | IO_L18N_T2_35 | G20 | +---------------+----------------+-----------------+------------------+ | PIN8 | EX_IO2_3P | IO_L18P_T2_35 | G19 | +---------------+----------------+-----------------+------------------+ | PIN9 | EX_IO2_4N | IO_L14N_T2_35 | H18 | +---------------+----------------+-----------------+------------------+ | PIN10 | EX_IO2_4P | IO_L14P_T2_35 | J18 | +---------------+----------------+-----------------+------------------+ | PIN11 | EX_IO2_5N | IO_L9N_T1_35 | L20 | +---------------+----------------+-----------------+------------------+ | PIN12 | EX_IO2_5P | IO_L9P_T1_35 | L19 | +---------------+----------------+-----------------+------------------+ | PIN13 | EX_IO2_6N | IO_L7N_T1_35 | M20 | +---------------+----------------+-----------------+------------------+ | PIN14 | EX_IO2_6P | IO_L7P_T1_35 | M19 | +---------------+----------------+-----------------+------------------+ | PIN15 | EX_IO2_7N | IO_L12N_T1_35 | K18 | +---------------+----------------+-----------------+------------------+ | PIN16 | EX_IO2_7P | IO_L12P_T1_35 | K17 | +---------------+----------------+-----------------+------------------+ | PIN17 | EX_IO2_8N | IO_L10N_T1_35 | J19 | +---------------+----------------+-----------------+------------------+ | PIN18 | EX_IO2_8P | IO_L10P_T1_35 | K19 | +---------------+----------------+-----------------+------------------+ | PIN19 | EX_IO2_9N | IO_L17N_T2_35 | H20 | +---------------+----------------+-----------------+------------------+ | PIN20 | EX_IO2_9P | IO_L17P_T2_35 | J20 | +---------------+----------------+-----------------+------------------+ | PIN21 | EX_IO2_10N | IO_L11N_T1_35 | L17 | +---------------+----------------+-----------------+------------------+ | PIN22 | EX_IO2_10P | IO_L11P_T1_35 | L16 | +---------------+----------------+-----------------+------------------+ | PIN23 | EX_IO2_11N | IO_L8N_T1_35 | M18 | +---------------+----------------+-----------------+------------------+ | PIN24 | EX_IO2_11P | IO_L8P_T1_35 | M17 | +---------------+----------------+-----------------+------------------+ | PIN25 | EX_IO2_12N | IO_L4N_T0_35 | D20 | +---------------+----------------+-----------------+------------------+ | PIN26 | EX_IO2_12P | IO_L4P_T0_35 | D19 | +---------------+----------------+-----------------+------------------+ | PIN27 | EX_IO2_13N | IO_L5N_T0_35 | E19 | +---------------+----------------+-----------------+------------------+ | PIN28 | EX_IO2_13P | IO_L5P_T0_35 | E18 | +---------------+----------------+-----------------+------------------+ | PIN29 | EX_IO2_14N | IO_L16N_T2_35 | G18 | +---------------+----------------+-----------------+------------------+ | PIN30 | EX_IO2_14P | IO_L16P_T2_35 | G17 | +---------------+----------------+-----------------+------------------+ | PIN31 | EX_IO2_15N | IO_L13N_T2_35 | H17 | +---------------+----------------+-----------------+------------------+ | PIN32 | EX_IO2_15P | IO_L13P_T2_35 | H16 | +---------------+----------------+-----------------+------------------+ | PIN33 | EX_IO2_16N | IO_L19N_T3_35 | G15 | +---------------+----------------+-----------------+------------------+ | PIN34 | EX_IO2_16P | IO_L19P_T3_35 | H15 | +---------------+----------------+-----------------+------------------+ | PIN35 | EX_IO2_17N | IO_L20N_T3_35 | J14 | +---------------+----------------+-----------------+------------------+ | PIN36 | EX_IO2_17P | IO_L20P_T3_35 | K14 | +---------------+----------------+-----------------+------------------+ | PIN37 | GND | - | - | +---------------+----------------+-----------------+------------------+ | PIN38 | GND | - | - | +---------------+----------------+-----------------+------------------+ | PIN39 | +3.3V | - | - | +---------------+----------------+-----------------+------------------+ | PIN40 | +3.3V | - | - | +---------------+----------------+-----------------+------------------+ 7.6 用户LED ----------- AX7020开发板的PL部分连接了4个LED发光二极管。4个用户LED部分的原理图如图6-6-1,LED灯的信号连接到PL部分BANK35的IO上。当PL部分BANK35的IO引脚输出为逻辑0时,LED会被点亮,出为逻辑1时,LED会被熄灭。 .. image:: images/media/image46.png :width: 4.67361in :height: 3.04653in 图7-13 PL用户LED原理图 图7-14为这四个LED实物图 .. image:: images/media/image47.png :width: 3.77014in :height: 0.9375in 图7-15 PL用户LED实物图 **PL用户LED引脚分配:** +---------------+--------------+------------+-------------------------+ | **信号名称** | **ZY | **ZY | **备注** | | | NQ引脚名** | NQ引脚号** | | +---------------+--------------+------------+-------------------------+ | LED1 | I | M14 | PL用户LED1灯 | | | O_L23P_T3_35 | | | +---------------+--------------+------------+-------------------------+ | LED2 | I | M15 | PL用户LED2灯 | | | O_L23N_T3_35 | | | +---------------+--------------+------------+-------------------------+ | LED3 | I | K16 | PL用户LED3灯 | | | O_L24P_T3_35 | | | +---------------+--------------+------------+-------------------------+ | LED4 | I | J16 | PL用户LED4灯 | | | O_L24N_T3_35 | | | +---------------+--------------+------------+-------------------------+ 7.7 用户按键 ------------ AX7020开发板的PL部分板载了4个用户按键(KEY1~KEY4), 按键的信号连接到ZYNQ的BANK34和BANK35的IO上。\ **按键都为低电平有效,** 没有按下时,信号为高;按键按下时,信号为低。4个用户按键的原理图如图7-16所示 .. image:: images/media/image48.png :width: 6.20833in :height: 3.51528in 图7-16个用户按键原理图 图7-17为连接到PL的4个用户按键实物图 .. image:: images/media/image49.png :width: 3.86389in :height: 1.75in 图7-17 4个PL用户按键实物图 **按键引脚分配:** +---------------+--------------+------------+-------------------------+ | **信号名称** | **ZY | **ZY | **备注** | | | NQ引脚名** | NQ引脚号** | | +---------------+--------------+------------+-------------------------+ | KEY1 | I | N15 | PL用户按键1 | | | O_L21P_T3_35 | | | +---------------+--------------+------------+-------------------------+ | KEY2 | I | N16 | PL用户按键2 | | | O_L21N_T3_35 | | | +---------------+--------------+------------+-------------------------+ | KEY3 | I | T17 | PL用户按键3 | | | O_L20P_T3_34 | | | +---------------+--------------+------------+-------------------------+ | KEY4 | I | R17 | PL用户按键4 | | | O_L19N_T3_34 | | | +---------------+--------------+------------+-------------------------+ .. |image1| image:: images/media/image1.png :width: 2.21111in :height: 0.54583in .. |image2| image:: images/media/image5.png .. |image3| image:: images/media/image12.png .. |image4| image:: images/media/image20.png :width: 5.73611in :height: 2.97569in