OpenEP3C5-C User Manual

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Overview

Basic operation and demo user guide of Waveshare FPGA Altera serial board[1] are in the present document for helping you quick start your FPGA development.

Hardware Design

This chapter mainly about the basic idea of core-board hardware design. Go with you to witness how a chip evolves to a board.
There are voltage regulator AMS1117, serial FLASH memory EPCS16, crystal oscillator, JTAG interface, LEDs, buttons, etc., beside main FPGA. Then, how and why do the devices connect together? What are their functions?

Framework of the Circuit

Core-board-circuit framework is shown in the following figure:
FPGA Cyclone Device Design.jpg

Power Supply Circuit

Power Supply Circuit is the basic circuit for normal operation. You can find voltage supplies details from the File:Cyclone-IV-Device-Handbook.pdf. Noting that EP3C5 requires 1.0V/1.2V for Internal core supply voltage (VCCINT) and PLL digital power supply (VCCD_PLL), requires 2.5V for PLL analog power supply (VCCA). Then I/O banks power supply VCCO can be connected to 1.2V, 1.5V, 1.8V, 2.5V, 3.0V, 3.3V to supply each area with different voltage standards. So for normal operation, the power supply of the board is designed for converting input voltage 5V to multiple voltages 3.3V, 2.5V, 1.2V. Meanwhile, a PWR LED is connected to 3.3V output, to meet the needs of checking power operation status. The schematic of the circuit:

Power Supply Circuit

Pin Name Description
VCC5 5V supply voltage, External Input
VCC33 3.3V voltage, converted from AMS1117-3.3, is generally used to supply the voltage of clock, configure circuit, special features pin high, etc.
VCC25 2.5V voltage, converted from AMS1117-2.5, is generally used to supply the voltage of VCCA.
VCC12 1.2V voltage, converted from AMS1117-1.2, is generally used to supply the voltage of VCCINT, VCC_PLL, etc.

Clock Circuit

The best solution of FPGA clock circuit is: A main clock, which is driven by dedicated global clock input(GCLK), controls each timing device of the design. Try to use global clock at any design. The FPGA has dedicated global clock pin, which is connected to each register of the device. The shortest time span of GCLK can supply is used for delay. We use a global clock interface CLK in our design, because it is single clock interface, we consider the use of active crystal clock as an external clock source. A 50MHz crystal oscillator on board is used for supply accurate clock. The schematic of the circuit:

Clock Circuit

Pin Name Description
CLK Clock input

Reset Circuit

The Reset Circuit contains RST Reset Circuit and nCONFIG Reconfigure Circuit. RST reset Circuit is a RC reset Circuit with RESET button switch, which is pressed to generate a Reset-signal, active-low. While nCONFIG Reset Circuit is triggered by nCONFIG key. FPGA will be reconfigured without reboot when the nCONFIG key is pressed. The schematic of the circuit:

Reset Circuit

Pin Name Description
RESET Active-low Reset
nCONFIG Active-low Reset, FPGA will be reconfigured, as soon as PROG_B pin restores to high level

Configuration/Programming Interface

Configuration is also known as loading and download. It is a process of FPGA programming. FPGA reconfigured at each reboot is a feature of SRAM-based FPGA. Within the FPGA, many programmable multiplexers, logic, interconnect nodes and RAM initialization, etc. are controlled by configuration data, which is stored in FPGA RAM.
The configured data of FPGA can be downloaded to target device with 3 methods, FPGA Active, FPGA Passive and JTAG, according to the role played in Configure Circuit. JTAG is an industry-standard interface. Usually All Altera FPGA can be configured via JTAG commands. Meanwhile, JTAG has more priority than other configuration method. Of course this board provides JTAG interface. The schematic of the circuit:
User can use dedicated Altera programmer USB Blaster to debug and program. File to be programmed to EPCS should be converted to .jic file by Quartus. That is, Set it as "JTAG Indirect Configuration File" and then uses the JTAG interface to program the EPCS device. See File:Cyclone-IV-Device-Handbook.pdf.

JTAG Interface

Pin Name Description
TDI Test data input. Serial input pin for instructions as well as test and programming data.
TDO Test data output. Serial data output pin for instructions as well as test and programming data.
TMS Test mode select. Input pin that provides the control signal to determine the transitions of the TAP controller state machine.
TCK Test clock input. The clock input to the BST circuitry.

Configuration Circuit

An EPCS16, Altera EPCS serial flash devices, is connected to the FPGA for keeping the data without power supplied. EPCS16 is one of advanced Configuration Device, 16Mbit density. It supports high capacity single configuration of FPGA. It also support in-system programming by JTAG interface. The schematic of the circuit:

Configuration Circuit

LED Circuit

4 LEDs onboard. Each LED is driven via one of the FPGA pins. When a low level inputs to LED pin, the corresponding LED turns on. The schematic of the circuit:

FPGA-LED-Circuit.png

Extention Board interface

Series of Open boards designed by Waveshare are based on Core-Extension-Separated idea. On the one hand, users can easily design extension circuit according to their needs, On the other hand, the interfaces of core board and extension board are fully considered about the compatible to other FPGA boards, make update easier.

Basic Operation

Power Up And Download

Power up CoreEP3C5 with 5V supply. Then the PWR_LED will light up in usual. The onboard JTAG interface is used for programming with dedicated programmer USB Blaster, as shown in the following figure:

Power up and connect USB Blaster

If you use CoreEP3C5 and OpenEP3C5-C together, just connect the core board to the mother board, and plug a 5V adapter directly without any jumper wire. Turn the switch on to power up.
Run the software Quartus II to download the Verilog and VHDL demo:

General Download Process

1. Copy the Nios II processors (Quartus II projects) to your computer, which are located in ".\nios\Quartus II Project".
2. Launch Nios II IDE
1) Create a new Nios II project.
2) Config the Nios processor by specifying the PTF file directory on the "Select Target Hardware" section. The PTF file directory depends on where you placed the Nios II processors in step 1.
3) Copy the corresponding c code in ".\nios\Nios II C Code" into the new project.
4) Build the new Nios II project.
3. Connect the development board to the PC through a download cable.
4. Back to the Nios II IDE
1) Download the Nios II processor to the FPGA, select"Tools->Quaters II Programmer" to download the sof file.
2) Run the Nios II project (right click the makefile, select "Run ->Run As->2 Nios II Hardware", it may takes several minutes). When download completed, the demo code should starts to run automatically.


Quick Start

All the following demo require power supply. Verilog, VHDL and NIOS are used in the following demos, please download the corresponding one.
An OpenEP4CE10-C development board is used for demonstration, other Altera boards are similar to it. If there are differences on any example, they will be special explained.

Light Up LEDs


Language

Verilog

VHDL

Nios II C

Sample Program Name

LED

LED_hello_world

Steps

  1. Connect the "SDRAM Board" to the SDRAM interface (required only for Nios II)
  2. Download the program

Phenomena

  • Onboard 4 LEDs flow from the left to the right.
  • LED keeps blinking;
  • The NOIS II project Console tab shows "hello_world"


JOYSTICK Demo


Language

Verilog

VHDL

Nios II C

Sample Program Name

JOYSTICK

Steps

  1. Set the jumper JOYSTICK JMP to on.
  2. Connect the “SDRAM Board” to the SDRAM interface (required only for Nios II)
  3. Download the program

Phenomena

  • LED status keeps changing according to the joystick pressed.


8 Push Buttons Demo


Language

Verilog

VHDL

Nios II C

Sample Program Name

8 Push Buttons

 ——

Steps

  1. Connect the "8 Push Buttons" to 8I/Os_1
  2. Download the program
 

Phenomena

  • LED turns on/off according to the pressed button

 


8 SEG LED Board Demo


Language

Verilog

VHDL

Nios II C

Sample Program Name

8 SEG LED Board

——

Steps

  1. Connect the "8 Push Buttons" to 16I/Os_2.
  2. Download the program
 

Phenomena

  • Display 0~E on the "8 SEG LED board"
 


4x4 Keypad Demo


Language

Verilog VHDL Nios II C

Sample Program Name

 4x4 Keypad

Steps

  1. Connect the "4x4 Keypad" to 8I/Os_1
  2. Download the program
 
  1. Connect the "4x4 Keypad" to 8I/Os_1
  2. Connect the "8 SEG LED board" to 16I/Os_2
  3. Download the program
 
  1. Connect the "4x4 Keypad" to 8I/Os_1
  2. Connect the “SDRAM Board” to the SDRAM interface
  3. Download the program

Phenomena

  • LED turns on/off according to the pressed button
  •  Display something on the "8 SEG LED board"
  • LED turns on/off according to the pressed button

DS18B20 Temperature Sensor Demo


Language

Verilog VHDL Nios II C

Sample Program Name

 DS18B20

Steps

  1. Connect the DS18B20+ to the ONE-WIRE socket
  2. Set the jumper 1-WIREJMP to on
  3. Connect the “8 SEG LED Board” to the 16I/Os_2
  4. Download the program
 
  1. Connect the DS18B20+ to the ONE-WIRE socket
  2. Set the jumper 1-WIREJMP to on
  3. Connect the LCD1602 to the LCD1602 interface, The LCD1602 pin 1 should correspond to the PCB printed mark "1" beside the onboard LCD connector
  4. Download the program
  1. Connect the DS18B20+ to the ONE-WIRE socket
  2. Set the jumper 1-WIREJMP to on
  3. Connect the “SDRAM Board” to the SDRAM interface
  4. Reboot the board

Phenomena

  • LCD1602 displays temperature
  • "8 SEG LED board" displays temperature
  • The Nios II Console tab displays temperature

Altera-DS18B20-Verilog.jpg Altera-DS18B20-VHDL.jpg

Buzzer Demo


Language

Verilog

VHDL

Nios II C

Sample Program Name

Buzzer/PWM

——

Steps

  1. Set the jumper Buzzer JMP to on
  2. Download the program
 

Phenomena

  • Buzzer will buzz.
 

PS/2 Keyboard Demo


Language

Verilog VHDL Nios II C

Sample Program Name

PS2

Steps

  1. Connect the "VGA PS2 Board" to 16I/Os_2, and connect a keyboard
  2. Connect the LCD1602 to the LCD1602 interface, The LCD1602 pin 1 should correspond to the PCB printed mark "1" beside the onboard LCD connector
  3. Download the program
  1. Connect the "VGA PS2 Board" to 16I/Os_2, and connect a keyboard
  2. Connect the “SDRAM Board” to the SDRAM interface
  3. Download the program
  4. Reboot the board

Phenomena

  • Characters inputted from keyboard are displayed on LCD1602
  • The corresponding ASCII inputted from keyboard are displayed on Console tab of Nios II software


VGA monitor Demo


Language

Verilog VHDL Nios II C

Sample Program Name

 VGA_color VGA  —— 

Steps

  1. Connect the "VGA PS2 Board" to 16I/Os_2, and connect a VGA monitor
  2. Download the program
 

Phenomena

  • Display something on the VGA monitor
 

LCD1602 Demo


Language

Verilog

VHDL

Nios II C

Sample Program Name

LCD1602

——

Steps

  1. Connect the LCD1602 to the LCD1602 interface, The LCD1602 pin 1 should correspond to the PCB printed mark "1" beside the onboard LCD connector
  2. Download the program
 

Phenomena

  • Display something on the "LCD1602"
 

LCD12864 Demo


Language

Verilog VHDL Nios II C

Sample Program Name

LCD12864   —— —— 

Steps

  1. Connect the LCD12864 to the LCD12864 interface
  2. Download the program
   

Phenomena

  • Display something on the "LCD12864"
   

Altera-LCD12864-Verilog.jpg

LCD32 touch screen Demo


Language

Verilog VHDL Nios II C

Sample Program Name

——  —— LCD32 

Steps

 
  1. Connect the "3.2inch 320x240 Touch LCD" to 32I/Os_2 interface via 3.2 inch LCD Adapter(B)
  2. Connect the “SDRAM Board” to the SDRAM interface
  3. Download the program
  4. After program downloaded, reboot the board.

Phenomena

 
  • Display something on the ""3.2inch 320x240 Touch LCD"", interact with it by touching (power

should be reset before downloading the demo code each time)

USB Communication Demo


Language

Verilog VHDL Nios II C

Sample Program Name

—— USB —— 

Steps

  1. Connect the "CY7C68013A USB Board" to 32I/Os_1, then connect it to PC
  2. Download the program
 

Phenomena


  • Control the onboard LED via USB_LED.exe
 

Remark


  • Before using CY7C68013A USB Board, please install driver EZ-USB.exe
 


SD-Card Demo


Language

Verilog VHDL Nios II C

Sample Program Name

—— —— SD-Card

Steps

  1. Connect the "Micro SD Storage Board" to 8I/Os_1
  2. Connect the “SDRAM Board” to the SDRAM interface
  3. Download the program
  4. Reboot the board

Phenomena


  • Place the MESSAGE.TXT file into SD card first, run the demo code, a new file hello.txt will be created.
  • The contents in MESSAGE.TXT will be displayed on the Console tab.


Ethernet Control Demo


Language

Verilog VHDL Nios II C

Sample Program Name

——  —— ENC28J60

Steps

 
  1. Connect the ""ENC28J60 Ethernet Board"" to 16I/Os_2, then connect it to the PC through an ethernet cable
  2. Download the program

Phenomena

 
  • The Internet Explorer shows information, follow the wizard on Internet Explorer
  • Numbers will be displayed on the Nios II Console tab


UART Demo


Language

Verilog VHDL Nios II C

Sample Program Name

UART

Steps

 
  1. Connect the "RS232 Board" to 8I/Os_1, then connect it to PC
  2. Download the program
  1. Connect the "RS232 Board" to 8I/Os_1, then connect it to PC
  2. Connect the "8 SEG LED Board" to 16I/Os_2
  3. Download the program
 
  1. Connect the "RS232 Board" to 8I/Os_1, then connect it to PC
  2. Connect the “SDRAM Board” to the SDRAM interface
  3. Download the program

Phenomena

  • Launch Serial Port Monitor, select a proper COM port, config the speed as 9600
  • Send any character/number via "Serial Port Monitor", and it should be sent back and displayed on "Serial Port Monitor" again.
  • Launch Serial Port Monitor, select a proper COM port, config the speed as 9600
  • Send any number via "Serial Port Monitor", and it should be displayed on the "8 SEG LED Board"
  • Switch to the Nios II Console tab, send any character, then send "t", the "t" will be detected.
  • Send "v" to close serial port debugging.


I2C EEPROM Demo


Language

Verilog VHDL Nios II C

Sample Program Name

 AT24CXX

Steps

  1. Connect the “AT24CXX EEPROM Board” to the 8I/Os_1 interface
  2. Connect the “8 SEG LED Board” to the 16I/Os_2 interface
  3. Download the program
 
  1. Connect the “AT24CXX EEPROM Board” to the 8I/Os_1 interface
  2. Connect the “8 SEG LED Board” to the 16I/Os_2 interface
  3. Connect the “SDRAM Board” to the SDRAM interface
  4. Download the program

Phenomena

  • Use the "8 SEG LED board" to display the data sent from SDRAM_L pins 3, 5, 7, 9 to "AT24CXX", and the data "AT24CXX" received, using one 8-segment digit for each data.
  • Short the SDRAM_R pin 5 and pin 6, then open them again, lastly short the SDRAM_R pin 3 and pin 4,data will be written into AT24CXX and then read from it to display on the "8 SEG LED board".
  • The LEDs as a binary number will be increased by 1 each time.

Remark

  • In the demo code, initially the SDRAM_L 3, 5, 7, 9 is set as pull-up input high-level, the SDRAM_L 4, 6, 8, 10 is set as output low-level. It is possible to config the written data by shorting the pins 3-4, 5-6, 7-8,9-10 respectively using jumper caps.

 


AT45DB Demo


Language

Verilog VHDL Nios II C

Sample Program Name

——  —— AT45DBXX

Steps

 
  1. Connect the "AT45DBXX DataFlash Board"to the 8I/Os_1 interface
  2. Connect the “SDRAM Board” to the SDRAM interface

Phenomena

 
  • The LEDs as a binary number will be increased by 1 each time.
  • Explanation: The program writes data(0~255) to AT45DB, then read from it. The data is displayed as binary form.

PCF8563 Demo


Language

Verilog VHDL Nios II C

Sample Program Name

——  —— PCF8563

Steps

 
  1. Connect the "PCF8563 RTC Board" to 8I/Os_1
  2. Connect the “SDRAM Board” to the SDRAM interface

Phenomena

 
  • The Nios II Console tab displays time

FT245 Demo


Language

Verilog VHDL Nios II C

Sample Program Name

——  —— FT245

Steps

 
  1. Connect the "FT245 USB FIFO Board" to 16I/Os_2, then connect it to PC
  2. Connect the “SDRAM Board” to the SDRAM interface
  3. Download the program

Phenomena

 
  • Send any character/number via "Serial Port Monitor", and it should be sent back and displayed on "Serial Port Monitor" again.

References