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CONTENTS
CHAPTER 1
DE1-SOC DEVELOPMENT KIT .......................................................................... 4
1.1 Package Contents ....................................................................................................................... 4
1.2 DE1-SoC System CD ................................................................................................................. 5
1.3 Getting Help ............................................................................................................................... 5
CHAPTER 2
INTRODUCTION OF THE DE1-SOC BOARD ..................................................... 6
2.1 Layout and Components............................................................................................................. 6
2.2 Block Diagram of the DE1-SoC Board ...................................................................................... 8
CHAPTER 3
USING THE DE1-SOC BOARD......................................................................... 12
3.1 Settings of FPGA Configuration Mode .................................................................................... 12
3.2 Configuration of Cyclone V SoC FPGA on DE1-SoC ............................................................. 13
3.3 Board Status Elements ............................................................................................................. 19
3.4 Board Reset Elements .............................................................................................................. 20
3.5 Clock Circuitry ......................................................................................................................... 21
3.6 Peripherals Connected to the FPGA......................................................................................... 23
3.6.1 User Push-buttons, Switches and LEDs ................................................................................ 23
3.6.2 7-segment Displays ............................................................................................................... 26
3.6.3 2x20 GPIO Expansion Headers............................................................................................. 28
3.6.4 24-bit Audio CODEC ............................................................................................................ 30
3.6.5 I2C Multiplexer ..................................................................................................................... 31
3.6.6 VGA ...................................................................................................................................... 32
3.6.7 TV Decoder ........................................................................................................................... 35
3.6.8 IR Receiver............................................................................................................................ 37
3.6.9 IR Emitter LED ..................................................................................................................... 37
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3.6.10 SDRAM Memory ................................................................................................................ 38
3.6.11 PS/2 Serial Port ................................................................................................................... 40
3.6.12 A/D Converter and 2x5 Header ........................................................................................... 42
3.7 Peripherals Connected to Hard Processor System (HPS)......................................................... 43
3.7.1 User Push-buttons and LEDs ................................................................................................ 43
3.7.2 Gigabit Ethernet .................................................................................................................... 44
3.7.3 UART .................................................................................................................................... 45
3.7.4 DDR3 Memory ...................................................................................................................... 46
3.7.5 Micro SD Card Socket .......................................................................................................... 48
3.7.6 2-port USB Host .................................................................................................................... 49
3.7.7 G-sensor ................................................................................................................................ 50
3.7.8 LTC Connector ...................................................................................................................... 51
CHAPTER 4
DE1-SOC SYSTEM BUILDER........................................................................... 53
4.1 Introduction .............................................................................................................................. 53
4.2 Design Flow ............................................................................................................................. 53
4.3 Using DE1-SoC System Builder .............................................................................................. 54
CHAPTER 5
EXAMPLES FOR FPGA .................................................................................... 60
5.1 DE1-SoC Factory Configuration .............................................................................................. 60
5.2 Audio Recording and Playing .................................................................................................. 61
5.3 Karaoke Machine ..................................................................................................................... 64
5.4 SDRAM Test in Nios II ............................................................................................................ 66
5.5 SDRAM Test in Verilog ........................................................................................................... 69
5.6 TV Box Demonstration ............................................................................................................ 71
5.7 PS/2 Mouse Demonstration ...................................................................................................... 73
5.8 IR Emitter LED and Receiver Demonstration ......................................................................... 76
5.9 ADC Reading ........................................................................................................................... 82
CHAPTER 6
EXAMPLES FOR HPS SOC ............................................................................... 85
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6.1 Hello Program .......................................................................................................................... 85
6.2 Users LED and KEY ................................................................................................................ 87
6.3 I2C Interfaced G-sensor ........................................................................................................... 93
6.4 I2C MUX Test .......................................................................................................................... 96
CHAPTER 7
EXAMPLES FOR USING BOTH HPS SOC AND FGPA ..................................... 99
7.1 HPS Control LED and HEX..................................................................................................... 99
7.2 DE1-SoC Control Panel ......................................................................................................... 103
7.3 DE1-SoC Linux Frame Buffer Project ................................................................................... 103
CHAPTER 8
PROGRAMMING THE EPCQ DEVICE ............................................................. 105
8.1 Before Programming Begins .................................................................................................. 105
8.2 Convert .SOF File to .JIC File................................................................................................ 105
8.3 Write JIC File into the EPCQ Device ..................................................................................... 110
8.4 Erase the EPCQ Device.......................................................................................................... 111
8.5 Nios II Boot from EPCQ Device in Quartus II v13.1 ............................................................ 112
CHAPTER 9
APPENDIX ........................................................................................................ 113
9.1 Revision History..................................................................................................................... 113
9.2 Copyright Statement ............................................................................................................... 113
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Chapter 1
DE1-SoC
Development Kit
The DE1-SoC Development Kit presents a robust hardware design platform built around the Altera
System-on-Chip (SoC) FPGA, which combines the latest dual-core Cortex-A9 embedded cores
with industry-leading programmable logic for ultimate design flexibility. Users can now leverage
the power of tremendous re-configurability paired with a high-performance, low-power processor
system. Altera’s SoC integrates an ARM-based hard processor system (HPS) consisting of processor,
peripherals and memory interfaces tied seamlessly with the FPGA fabric using a high-bandwidth
interconnect backbone. The DE1-SoC development board is equipped with high-speed DDR3
memory, video and audio capabilities, Ethernet networking, and much more that promise many
exciting applications.
The DE1-SoC Development Kit contains all the tools needed to use the board in conjunction with a
computer that runs the Microsoft Windows XP or later.
1.1 Package Contents
Figure 1-1 shows a photograph of the DE1-SoC package.
Figure 1-1 The DE1-SoC package contents
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The DE1-SoC package includes:
The DE1-SoC development board
DE1-SoC Quick Start Guide
USB cable (Type A to B) for FPGA programming and control
USB cable (Type A to Mini-B) for UART control
12V DC power adapter
1.2 DE1-SoC System CD
The DE1-SoC System CD contains all the documents and supporting materials associated with
DE1-SoC, including the user manual, system builder, reference designs, and device datasheets.
Users can download this system CD from the link: http://cd-de1-soc.terasic.com.
1.3 Getting Help
Here are the addresses where you can get help if you encounter any problems:
Altera Corporation
101 Innovation Drive San Jose, California, 95134 USA
Email: university@altera.com
Terasic Technologies
9F., No.176, Sec.2, Gongdao 5th Rd, East Dist, Hsinchu City, 30070. Taiwan
Email: support@terasic.com
Tel.: +886-3-575-0880
Website: de1-soc.terasic.com
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Chapter 2
Introduction of the
DE1-SoC Board
This chapter provides an introduction to the features and design characteristics of the board.
2.1 Layout and Components
Figure 2-1 shows a photograph of the board. It depicts the layout of the board and indicates the
location of the connectors and key components.
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Figure 2-1 DE1-SoC development board (top view)
Figure 2-2 De1-SoC development board (bottom view)
The DE1-SoC board has many features that allow users to implement a wide range of designed
circuits, from simple circuits to various multimedia projects.
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The following hardware is provided on the board:
FPGA
Altera Cyclone® V SE 5CSEMA5F31C6N device
Altera serial configuration device – EPCQ256
USB-Blaster II onboard for programming; JTAG Mode
64MB SDRAM (16-bit data bus)
4 push-buttons
10 slide switches
10 red user LEDs
Six 7-segment displays
Four 50MHz clock sources from the clock generator
24-bit CD-quality audio CODEC with line-in, line-out, and microphone-in jacks
VGA DAC (8-bit high-speed triple DACs) with VGA-out connector
TV decoder (NTSC/PAL/SECAM) and TV-in connector
PS/2 mouse/keyboard connector
IR receiver and IR emitter
Two 40-pin expansion header with diode protection
A/D converter, 4-pin SPI interface with FPGA
HPS (Hard Processor System)
800MHz Dual-core ARM Cortex-A9 MPCore processor
1GB DDR3 SDRAM (32-bit data bus)
1 Gigabit Ethernet PHY with RJ45 connector
2-port USB Host, normal Type-A USB connector
Micro SD card socket
Accelerometer (I2C interface + interrupt)
UART to USB, USB Mini-B connector
Warm reset button and cold reset button
One user button and one user LED
LTC 2x7 expansion header
2.2 Block Diagram of the DE1-SoC Board
Figure 2-3 is the block diagram of the board. All the connections are established through the
Cyclone V SoC FPGA device to provide maximum flexibility for users. Users can configure the
FPGA to implement any system design.
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Figure 2-3 Block diagram of DE1-SoC
Detailed information about Figure 2-3 are listed below.
FPGA Device
Cyclone V SoC 5CSEMA5F31 Device
Dual-core ARM Cortex-A9 (HPS)
85K programmable logic elements
4,450 Kbits embedded memory
6 fractional PLLs
2 hard memory controllers
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Configuration and Debug
Quad serial configuration device – EPCQ256 on FPGA
Onboard USB-Blaster II (normal type B USB connector)
Memory Device
64MB (32Mx16) SDRAM on FPGA
1GB (2x256Mx16) DDR3 SDRAM on HPS
Micro SD card socket on HPS
Communication
Two port USB 2.0 Host (ULPI interface with USB type A connector)
UART to USB (USB Mini-B connector)
10/100/1000 Ethernet
PS/2 mouse/keyboard
IR emitter/receiver
I2C multiplexer
Connectors
Two 40-pin expansion headers
One 10-pin ADC input header
One LTC connector (one Serial Peripheral Interface (SPI) Master ,one I2C and one GPIO
interface )
Display
24-bit VGA DAC
Audio
24-bit CODEC, Line-in, Line-out, and microphone-in jacks
Video Input
TV decoder (NTSC/PAL/SECAM) and TV-in connector
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ADC
Fast throughput rate: 1 MSPS
Channel number: 8
Resolution: 12-bit
Analog input range : 0 ~ 2.5 V or 0 ~ 5V as selected via the RANGE bit in the control register
Switches, Buttons, and Indicators
5 user Keys (FPGA x4, HPS x1)
10 user switches (FPGA x10)
11 user LEDs (FPGA x10, HPS x 1)
2 HPS reset buttons (HPS_RESET_n and HPS_WARM_RST_n)
Six 7-segment displays
Sensors
G-Sensor on HPS
Power
12V DC input
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Chapter 3
Using the DE1-SoC
Board
This chapter provides an instruction to use the board and describes the peripherals.
3.1 Settings of FPGA Configuration Mode
When the DE1-SoC board is powered on, the FPGA can be configured from EPCQ or HPS. The
MSEL[4:0] pins are used to select the configuration scheme. It is implemented as a 6-pin DIP
switch SW10 on the DE1-SoC board, as shown in Figure 3-1.
Figure 3-1 DIP switch (SW10) setting of Active Serial (AS) mode at the back of DE1-SoC board
Table 3-1 shows the relation between MSEL[4:0] and DIP switch (SW10).
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Table 3-1 FPGA Configuration Mode Switch (SW10)
Board Reference Signal Name
SW10.1
SW10.2
SW10.3
SW10.4
SW10.5
SW10.6
MSEL0
MSEL1
MSEL2
MSEL3
MSEL4
N/A
Description
Use these pins to set the FPGA
Configuration scheme
N/A
Default
ON (“0”)
OFF (“1”)
ON (“0”)
ON (“0”)
OFF (“1”)
N/A
Figure 3-1 shows MSEL[4:0] setting of AS mode, which is also the default setting on DE1-SoC.
When the board is powered on, the FPGA is configured from EPCQ, which is pre-programmed with
the default code. If developers wish to reconfigure FPGA from an application software running on
Linux, the MSEL[4:0] needs to be set to “01010” before the programming process begins. If
developers using the "Linux Console with frame buffer" or "Linux LXDE Desktop" SD Card image,
the MSEL[4:0] needs to be set to “00000” before the board is powered on.
Table 3-2 MSEL Pin Settings for FPGA Configure of DE1-SoC
MSEL[4:0]
Configure Scheme
Description
10010
01010
AS
FPPx32
00000
FPPx16
FPGA configured from EPCQ (default)
FPGA configured from HPS software: Linux
FPGA configured from HPS software: U-Boot, with
image stored on the SD card, like LXDE Desktop or
console Linux with frame buffer edition.
3.2 Configuration of Cyclone V SoC FPGA on DE1-SoC
There are two types of programming method supported by DE1-SoC:
1.
JTAG programming: It is named after the IEEE standards Joint Test Action Group.
The configuration bit stream is downloaded directly into the Cyclone V SoC FPGA. The FPGA will
retain its current status as long as the power keeps applying to the board; the configuration
information will be lost when the power is off.
2.
AS programming: The other programming method is Active Serial configuration.
The configuration bit stream is downloaded into the quad serial configuration device (EPCQ256),
which provides non-volatile storage for the bit stream. The information is retained within EPCQ256
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even if the DE1-SoC board is turned off. When the board is powered on, the configuration data in
the EPCQ256 device is automatically loaded into the Cyclone V SoC FPGA.
JTAG Chain on DE1-SoC Board
The FPGA device can be configured through JTAG interface on DE1-SoC board, but the JTAG
chain must form a closed loop, which allows Quartus II programmer to the detect FPGA device.
Figure 3-2 illustrates the JTAG chain on DE1-SoC board.
Figure 3-2 Path of the JTAG chain
Configure the FPGA in JTAG Mode
There are two devices (FPGA and HPS) on the JTAG chain. The following shows how the FPGA is
programmed in JTAG mode step by step.
1. Open the Quartus II programmer and click “Auto Detect”, as circled in Figure 3-3
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Figure 3-3 Detect FPGA device in JTAG mode
2. Select detected device associated with the board, as circled in Figure 3-4.
Figure 3-4 Select 5CSEMA5 device
3. Both FPGA and HPS are detected, as shown in Figure 3-5.
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Figure 3-5 FPGA and HPS detected in Quartus programmer
4. Right click on the FPGA device and open the .sof file to be programmed, as highlighted in
Figure 3-6.
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Figure 3-6 Open the .sof file to be programmed into the FPGA device
5. Select the .sof file to be programmed, as shown in Figure 3-7.
Figure 3-7 Select the .sof file to be programmed into the FPGA device
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6. Click “Program/Configure” check box and then click “Start” button to download the .sof file
into the FPGA device, as shown in Figure 3-8.
Figure 3-8 Program .sof file into the FPGA device
Configure the FPGA in AS Mode
The DE1-SoC board uses a quad serial configuration device (EPCQ256) to store configuration
data for the Cyclone V SoC FPGA. This configuration data is automatically loaded from the
quad serial configuration device chip into the FPGA when the board is powered up.
Users need to use Serial Flash Loader (SFL) to program the quad serial configuration device
via JTAG interface. The FPGA-based SFL is a soft intellectual property (IP) core within the
FPGA that bridge the JTAG and Flash interfaces. The SFL Megafunction is available in
Quartus II. Figure 3-9 shows the programming method when adopting SFL solution.
Please refer to Chapter 9: Steps of Programming the Quad Serial Configuration Device for the
basic programming instruction on the serial configuration device.
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Figure 3-9 Programming a quad serial configuration device with SFL solution
3.3 Board Status Elements
In addition to the 10 LEDs that FPGA device can control, there are 5 indicators which can indicate
the board status (See Figure 3-10), please refer the details in Table 3-3
Figure 3-10 LED Indicators on DE1-SoC
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Table 3-3 LED Indicators
Board Reference
LED Name
Description
D14
12-V Power
Illuminate when 12V power is active.
TXD
UART TXD
Illuminate when data is transferred from FT232R to USB Host.
RXD
UART RXD
Illuminate when data is transferred from USB Host to FT232R.
D5
JTAG_RX
Reserved
D4
JTAG_TX
3.4 Board Reset Elements
There are two HPS reset buttons on DE1-SoC, HPS (cold) reset and HPS warm reset, as shown in
Figure 3-11. Table 3-4 describes the purpose of these two HPS reset buttons. Figure 3-12 is the
reset tree for DE1-SoC.
Figure 3-11 HPS cold reset and warm reset buttons on DE1-SoC
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Table 3-4 Description of Two HPS Reset Buttons on DE1-SoC
Board Reference Signal Name
KEY5
KEY7
Description
Cold reset to the HPS, Ethernet PHY and USB host device.
Active low input which resets all HPS logics that can be reset.
Warm reset to the HPS block. Active low input affects the
HPS_WARM_RST_N
system reset domain for debug purpose.
HPS_RESET_N
Figure 3-12 HPS reset tree on DE1-SoC board
3.5 Clock Circuitr y
Figure 3-13 shows the default frequency of all external clocks to the Cyclone V SoC FPGA. A
clock generator is used to distribute clock signals with low jitter. The four 50MHz clock signals
connected to the FPGA are used as clock sources for user logic. One 25MHz clock signal is
connected to two HPS clock inputs, and the other one is connected to the clock input of Gigabit
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Ethernet Transceiver. Two 24MHz clock signals are connected to the clock inputs of USB
Host/OTG PHY and USB hub controller. The associated pin assignment for clock inputs to FPGA
I/O pins is listed in Table 3-5.
Figure 3-13 Block diagram of the clock distribution on DE1-SoC
Table 3-5 Pin Assignment of Clock Inputs
Signal Name
CLOCK_50
CLOCK2_50
CLOCK3_50
CLOCK4_50
HPS_CLOCK1_25
HPS_CLOCK2_25
FPGA Pin No.
PIN_AF14
PIN_AA16
PIN_Y26
PIN_K14
PIN_D25
PIN_F25
DE1-SoC User Manual
Description
50 MHz clock input
50 MHz clock input
50 MHz clock input
50 MHz clock input
25 MHz clock input
25 MHz clock input
22
I/O Standard
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
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3.6 Peripherals Connected to the FPGA
This section describes the interfaces connected to the FPGA. Users can control or monitor different
interfaces with user logic from the FPGA.
3.6.1 User Push-buttons, Switches and LEDs
The board has four push-buttons connected to the FPGA, as shown in Figure 3-14 Connections
between the push-buttons and the Cyclone V SoC FPGA. Schmitt trigger circuit is implemented and act
as switch debounce in Figure 3-15 for the push-buttons connected. The four push-buttons named
KEY0, KEY1, KEY2, and KEY3 coming out of the Schmitt trigger device are connected directly to
the Cyclone V SoC FPGA. The push-button generates a low logic level or high logic level when it
is pressed or not, respectively. Since the push-buttons are debounced, they can be used as clock or
reset inputs in a circuit.
Figure 3-14 Connections between the push-buttons and the Cyclone V SoC FPGA
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Pushbutton depressed
Pushbutton released
Before
Debouncing
Schmitt Trigger
Debounced
Figure 3-15 Switch debouncing
There are ten slide switches connected to the FPGA, as shown in Figure 3-16. These switches are
not debounced and to be used as level-sensitive data inputs to a circuit. Each switch is connected
directly and individually to the FPGA. When the switch is set to the DOWN position (towards the
edge of the board), it generates a low logic level to the FPGA. When the switch is set to the UP
position, a high logic level is generated to the FPGA.
Figure 3-16 Connections between the slide switches and the Cyclone V SoC FPGA
There are also ten user-controllable LEDs connected to the FPGA. Each LED is driven directly and
individually by the Cyclone V SoC FPGA; driving its associated pin to a high logic level or low
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level to turn the LED on or off, respectively. Figure 3-17 shows the connections between LEDs and
Cyclone V SoC FPGA. Table 3-6, Table 3-7 and Table 3-8 list the pin assignment of user
push-buttons, switches, and LEDs.
Figure 3-17 Connections between the LEDs and the Cyclone V SoC FPGA
Table 3-6 Pin Assignment of Slide Switches
Signal Name
SW[0]
SW[1]
SW[2]
SW[3]
SW[4]
SW[5]
SW[6]
SW[7]
SW[8]
SW[9]
FPGA Pin No.
PIN_AB12
PIN_AC12
PIN_AF9
PIN_AF10
PIN_AD11
PIN_AD12
PIN_AE11
PIN_AC9
PIN_AD10
PIN_AE12
Description
Slide Switch[0]
Slide Switch[1]
Slide Switch[2]
Slide Switch[3]
Slide Switch[4]
Slide Switch[5]
Slide Switch[6]
Slide Switch[7]
Slide Switch[8]
Slide Switch[9]
I/O Standard
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
Table 3-7 Pin Assignment of Push-buttons
Signal Name
KEY[0]
KEY[1]
KEY[2]
KEY[3]
FPGA Pin No.
PIN_AA14
PIN_AA15
PIN_W15
PIN_Y16
DE1-SoC User Manual
Description
Push-button[0]
Push-button[1]
Push-button[2]
Push-button[3]
25
I/O Standard
3.3V
3.3V
3.3V
3.3V
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Table 3-8 Pin Assignment of LEDs
Signal Name
LEDR[0]
LEDR[1]
LEDR[2]
LEDR[3]
LEDR[4]
LEDR[5]
LEDR[6]
LEDR[7]
LEDR[8]
LEDR[9]
FPGA Pin No.
PIN_V16
PIN_W16
PIN_V17
PIN_V18
PIN_W17
PIN_W19
PIN_Y19
PIN_W20
PIN_W21
PIN_Y21
Description
LED [0]
LED [1]
LED [2]
LED [3]
LED [4]
LED [5]
LED [6]
LED [7]
LED [8]
LED [9]
I/O Standard
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.6.2 7-segment Displays
The DE1-SoC board has six 7-segment displays. These displays are paired to display numbers in
various sizes. Figure 3-18 shows the connection of seven segments (common anode) to pins on
Cyclone V SoC FPGA. The segment can be turned on or off by applying a low logic level or high
logic level from the FPGA, respectively.
Each segment in a display is indexed from 0 to 6, with corresponding positions given in Figure
3-18. Table 3-9 shows the pin assignment of FPGA to the 7-segment displays.
Figure 3-18 Connections between the 7-segment display HEX0 and the Cyclone V SoC FPGA
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Table 3-9 Pin Assignment of 7-segment Displays
Signal Name
HEX0[0]
HEX0[1]
HEX0[2]
HEX0[3]
HEX0[4]
HEX0[5]
HEX0[6]
HEX1[0]
HEX1[1]
HEX1[2]
HEX1[3]
HEX1[4]
HEX1[5]
HEX1[6]
HEX2[0]
HEX2[1]
HEX2[2]
HEX2[3]
HEX2[4]
HEX2[5]
HEX2[6]
HEX3[0]
HEX3[1]
HEX3[2]
HEX3[3]
HEX3[4]
HEX3[5]
HEX3[6]
HEX4[0]
HEX4[1]
HEX4[2]
HEX4[3]
HEX4[4]
HEX4[5]
HEX4[6]
HEX5[0]
HEX5[1]
HEX5[2]
HEX5[3]
HEX5[4]
HEX5[5]
HEX5[6]
FPGA Pin No.
PIN_AE26
PIN_AE27
PIN_AE28
PIN_AG27
PIN_AF28
PIN_AG28
PIN_AH28
PIN_AJ29
PIN_AH29
PIN_AH30
PIN_AG30
PIN_AF29
PIN_AF30
PIN_AD27
PIN_AB23
PIN_AE29
PIN_AD29
PIN_AC28
PIN_AD30
PIN_AC29
PIN_AC30
PIN_AD26
PIN_AC27
PIN_AD25
PIN_AC25
PIN_AB28
PIN_AB25
PIN_AB22
PIN_AA24
PIN_Y23
PIN_Y24
PIN_W22
PIN_W24
PIN_V23
PIN_W25
PIN_V25
PIN_AA28
PIN_Y27
PIN_AB27
PIN_AB26
PIN_AA26
PIN_AA25
DE1-SoC User Manual
Description
Seven Segment Digit 0[0]
Seven Segment Digit 0[1]
Seven Segment Digit 0[2]
Seven Segment Digit 0[3]
Seven Segment Digit 0[4]
Seven Segment Digit 0[5]
Seven Segment Digit 0[6]
Seven Segment Digit 1[0]
Seven Segment Digit 1[1]
Seven Segment Digit 1[2]
Seven Segment Digit 1[3]
Seven Segment Digit 1[4]
Seven Segment Digit 1[5]
Seven Segment Digit 1[6]
Seven Segment Digit 2[0]
Seven Segment Digit 2[1]
Seven Segment Digit 2[2]
Seven Segment Digit 2[3]
Seven Segment Digit 2[4]
Seven Segment Digit 2[5]
Seven Segment Digit 2[6]
Seven Segment Digit 3[0]
Seven Segment Digit 3[1]
Seven Segment Digit 3[2]
Seven Segment Digit 3[3]
Seven Segment Digit 3[4]
Seven Segment Digit 3[5]
Seven Segment Digit 3[6]
Seven Segment Digit 4[0]
Seven Segment Digit 4[1]
Seven Segment Digit 4[2]
Seven Segment Digit 4[3]
Seven Segment Digit 4[4]
Seven Segment Digit 4[5]
Seven Segment Digit 4[6]
Seven Segment Digit 5[0]
Seven Segment Digit 5[1]
Seven Segment Digit 5[2]
Seven Segment Digit 5[3]
Seven Segment Digit 5[4]
Seven Segment Digit 5[5]
Seven Segment Digit 5[6]
27
I/O Standard
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
www.terasic.com
April 8, 2015
3.6.3 2x20 GPIO Expansion Headers
The board has two 40-pin expansion headers. Each header has 36 user pins connected directly to the
Cyclone V SoC FPGA. It also comes with DC +5V (VCC5), DC +3.3V (VCC3P3), and two GND
pins. The maximum power consumption allowed for a daughter card connected to one or two GPIO
ports is shown in Table 3-10.
Table 3-10 Voltage and Max. Current Limit of Expansion Header(s)
Supplied Voltage
5V
3.3V
Max. Current Limit
1A
1.5A
Each pin on the expansion headers is connected to two diodes and a resistor for protection against
high or low voltage level. Figure 3-19 shows the protection circuitry applied to all 2x36 data pins.
Table 3-11 shows the pin assignment of two GPIO headers.
Figure 3-19 Connections between the GPIO header and Cyclone V SoC FPGA
Table 3-11 Pin Assignment of Expansion Headers
Signal Name
GPIO_0[0]
GPIO_0 [1]
GPIO_0 [2]
GPIO_0 [3]
FPGA Pin No.
PIN_AC18
PIN_Y17
PIN_AD17
PIN_Y18
DE1-SoC User Manual
Description
GPIO Connection 0[0]
GPIO Connection 0[1]
GPIO Connection 0[2]
GPIO Connection 0[3]
28
I/O Standard
3.3V
3.3V
3.3V
3.3V
www.terasic.com
April 8, 2015
GPIO_0 [4]
GPIO_0 [5]
GPIO_0 [6]
GPIO_0 [7]
GPIO_0 [8]
GPIO_0 [9]
GPIO_0 [10]
GPIO_0 [11]
GPIO_0 [12]
GPIO_0 [13]
GPIO_0 [14]
GPIO_0 [15]
GPIO_0 [16]
GPIO_0 [17]
GPIO_0 [18]
GPIO_0 [19]
GPIO_0 [20]
GPIO_0 [21]
GPIO_0 [22]
GPIO_0 [23]
GPIO_0 [24]
GPIO_0 [25]
GPIO_0 [26]
GPIO_0 [27]
GPIO_0 [28]
GPIO_0 [29]
GPIO_0 [30]
GPIO_0 [31]
GPIO_0 [32]
GPIO_0 [33]
GPIO_0 [34]
GPIO_0 [35]
GPIO_1[0]
GPIO_1[1]
GPIO_1 [2]
GPIO_1 [3]
GPIO_1 [4]
GPIO_1 [5]
GPIO_1 [6]
GPIO_1 [7]
GPIO_1 [8]
GPIO_1 [9]
GPIO_1[10]
GPIO_1 [11]
PIN_AK16
PIN_AK18
PIN_AK19
PIN_AJ19
PIN_AJ17
PIN_AJ16
PIN_AH18
PIN_AH17
PIN_AG16
PIN_AE16
PIN_AF16
PIN_AG17
PIN_AA18
PIN_AA19
PIN_AE17
PIN_AC20
PIN_AH19
PIN_AJ20
PIN_AH20
PIN_AK21
PIN_AD19
PIN_AD20
PIN_AE18
PIN_AE19
PIN_AF20
PIN_AF21
PIN_AF19
PIN_AG21
PIN_AF18
PIN_AG20
PIN_AG18
PIN_AJ21
PIN_AB17
PIN_AA21
PIN_AB21
PIN_AC23
PIN_AD24
PIN_AE23
PIN_AE24
PIN_AF25
PIN_AF26
PIN_AG25
PIN_AG26
PIN_AH24
DE1-SoC User Manual
GPIO Connection 0[4]
GPIO Connection 0[5]
GPIO Connection 0[6]
GPIO Connection 0[7]
GPIO Connection 0[8]
GPIO Connection 0[9]
GPIO Connection 0[10]
GPIO Connection 0[11]
GPIO Connection 0[12]
GPIO Connection 0[13]
GPIO Connection 0[14]
GPIO Connection 0[15]
GPIO Connection 0[16]
GPIO Connection 0[17]
GPIO Connection 0[18]
GPIO Connection 0[19]
GPIO Connection 0[20]
GPIO Connection 0[21]
GPIO Connection 0[22]
GPIO Connection 0[23]
GPIO Connection 0[24]
GPIO Connection 0[25]
GPIO Connection 0[26]
GPIO Connection 0[27]
GPIO Connection 0[28]
GPIO Connection 0[29]
GPIO Connection 0[30]
GPIO Connection 0[31]
GPIO Connection 0[32]
GPIO Connection 0[33]
GPIO Connection 0[34]
GPIO Connection 0[35]
GPIO Connection 1[0]
GPIO Connection 1[1]
GPIO Connection 1[2]
GPIO Connection 1[3]
GPIO Connection 1[4]
GPIO Connection 1[5]
GPIO Connection 1[6]
GPIO Connection 1[7]
GPIO Connection 1[8]
GPIO Connection 1[9]
GPIO Connection 1[10]
GPIO Connection 1[11]
29
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
www.terasic.com
April 8, 2015
GPIO_1 [12]
GPIO_1 [13]
GPIO_1 [14]
GPIO_1 [15]
GPIO_1 [16]
GPIO_1 [17]
GPIO_1 [18]
GPIO_1 [19]
GPIO_1 [20]
GPIO_1 [21]
GPIO_1 [22]
GPIO_1 [23]
GPIO_1 [24]
GPIO_1 [25]
GPIO_1 [26]
GPIO_1 [27]
GPIO_1 [28]
GPIO_1 [29]
GPIO_1 [30]
GPIO_1 [31]
GPIO_1 [32]
GPIO_1 [33]
GPIO_1 [34]
GPIO_1 [35]
PIN_AH27
PIN_AJ27
PIN_AK29
PIN_AK28
PIN_AK27
PIN_AJ26
PIN_AK26
PIN_AH25
PIN_AJ25
PIN_AJ24
PIN_AK24
PIN_AG23
PIN_AK23
PIN_AH23
PIN_AK22
PIN_AJ22
PIN_AH22
PIN_AG22
PIN_AF24
PIN_AF23
PIN_AE22
PIN_AD21
PIN_AA20
PIN_AC22
GPIO Connection 1[12]
GPIO Connection 1[13]
GPIO Connection 1[14]
GPIO Connection 1[15]
GPIO Connection 1[16]
GPIO Connection 1[17]
GPIO Connection 1[18]
GPIO Connection 1[19]
GPIO Connection 1[20]
GPIO Connection 1[21]
GPIO Connection 1[22]
GPIO Connection 1[23]
GPIO Connection 1[24]
GPIO Connection 1[25]
GPIO Connection 1[26]
GPIO Connection 1[27]
GPIO Connection 1[28]
GPIO Connection 1[29]
GPIO Connection 1[30]
GPIO Connection 1[31]
GPIO Connection 1[32]
GPIO Connection 1[33]
GPIO Connection 1[34]
GPIO Connection 1[35]
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.6.4 24-bit Audio CODEC
The DE1-SoC board offers high-quality 24-bit audio via the Wolfson WM8731 audio CODEC
(Encoder/Decoder). This chip supports microphone-in, line-in, and line-out ports, with adjustable
sample rate from 8 kHz to 96 kHz. The WM8731 is controlled via serial I2C bus, which is
connected to HPS or Cyclone V SoC FPGA through an I2C multiplexer. The connection of the
audio circuitry to the FPGA is shown in Figure 3-20, and the associated pin assignment to the
FPGA is listed in Table 3-12. More information about the WM8731 codec is available in its
datasheet, which can be found on the manufacturer’s website, or in the directory
\DE1_SOC_datasheets\Audio CODEC of DE1-SoC System CD.
DE1-SoC User Manual
30
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April 8, 2015
Figure 3-20 Connections between the FPGA and audio CODEC
Table 3-12 Pin Assignment of Audio CODEC
Signal Name
AUD_ADCLRCK
AUD_ADCDAT
AUD_DACLRCK
AUD_DACDAT
AUD_XCK
AUD_BCLK
I2C_SCLK
I2C_SDAT
FPGA Pin No.
PIN_K8
PIN_K7
PIN_H8
PIN_J7
PIN_G7
PIN_H7
PIN_J12 or PIN_E23
PIN_K12 or PIN_C24
Description
Audio CODEC ADC LR Clock
Audio CODEC ADC Data
Audio CODEC DAC LR Clock
Audio CODEC DAC Data
Audio CODEC Chip Clock
Audio CODEC Bit-stream Clock
I2C Clock
I2C Data
I/O Standard
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.6.5 I2C Multiplexer
The DE1-SoC board implements an I2C multiplexer for HPS to access the I2C bus originally
owned by FPGA. Figure 3-21 shows the connection of I2C multiplexer to the FPGA and HPS. HPS
can access Audio CODEC and TV Decoder if and only if the HPS_I2C_CONTROL signal is set to
high. The pin assignment of I2C bus is listed in Table 3-13 .
DE1-SoC User Manual
31
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April 8, 2015
Figure 3-21 Control mechanism for the I2C multiplexer
Table 3-13 Pin Assignment of I2C Bus
Signal Name
FPGA_I2C_SCLK
FPGA_I2C_SDAT
HPS_I2C1_SCLK
HPS_I2C1_SDAT
HPS_I2C2_SCLK
HPS_I2C2_SDAT
FPGA Pin No.
PIN_J12
PIN_K12
PIN_E23
PIN_C24
PIN_H23
PIN_A25
Description
FPGA I2C Clock
FPGA I2C Data
I2C Clock of the first HPS I2C concontroller
I2C Data of the first HPS I2C concontroller
I2C Clock of the second HPS I2C concontroller
I2C Data of the second HPS I2C concontroller
I/O Standard
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.6.6 VGA
The DE1-SoC board has a 15-pin D-SUB connector populated for VGA output. The VGA
synchronization signals are generated directly from the Cyclone V SoC FPGA, and the Analog
Devices ADV7123 triple 10-bit high-speed video DAC (only the higher 8-bits are used) transforms
signals from digital to analog to represent three fundamental colors (red, green, and blue). It can
support up to SXGA standard (1280*1024) with signals transmitted at 100MHz. Figure 3-22 shows
the signals connected between the FPGA and VGA.
DE1-SoC User Manual
32
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April 8, 2015
Figure 3-22 Connections between the FPGA and VGA
The timing specification for VGA synchronization and RGB (red, green, blue) data can be easily
found on website nowadays. Figure 3-22 illustrates the basic timing requirements for each row
(horizontal) displayed on a VGA monitor. An active-low pulse of specific duration is applied to the
horizontal synchronization (hsync) input of the monitor, which signifies the end of one row of data
and the start of the next. The data (RGB) output to the monitor must be off (driven to 0 V) for a
time period called the back porch (b) after the hsync pulse occurs, which is followed by the display
interval (c). During the data display interval the RGB data drives each pixel in turn across the row
being displayed. Finally, there is a time period called the front porch (d) where the RGB signals
must again be off before the next hsync pulse can occur. The timing of vertical synchronization
(vsync) is similar to the one shown in Figure 3-23, except that a vsync pulse signifies the end of
one frame and the start of the next, and the data refers to the set of rows in the frame (horizontal
timing). Table 3-14 and Table 3-15 show different resolutions and durations of time period a, b, c,
and d for both horizontal and vertical timing.
More information about the ADV7123 video DAC is available in its datasheet, which can be found
on the manufacturer’s website, or in the directory \Datasheets\VIDEO DAC of DE1-SoC System
CD. The pin assignment between the Cyclone V SoC FPGA and the ADV7123 is listed in Table
3-16.
DE1-SoC User Manual
33
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April 8, 2015
Figure 3-23 VGA horizontal timing specification
Table 3-14 VGA Horizontal Timing Specification
VGA mode
Horizontal Timing Spec
Configuration
VGA(60Hz)
Resolution(HxV)
640x480
a(us)
3.8
b(us)
1.9
c(us)
25.4
d(us)
0.6
Pixel clock(MHz)
25
VGA(85Hz)
640x480
1.6
2.2
17.8
1.6
36
SVGA(60Hz)
800x600
3.2
2.2
20
1
40
SVGA(75Hz)
800x600
1.6
3.2
16.2
0.3
49
SVGA(85Hz)
800x600
1.1
2.7
14.2
0.6
56
XGA(60Hz)
1024x768
2.1
2.5
15.8
0.4
65
XGA(70Hz)
1024x768
1.8
1.9
13.7
0.3
75
XGA(85Hz)
1024x768
1.0
2.2
10.8
0.5
95
1280x1024(60Hz)
1280x1024
1.0
2.3
11.9
0.4
108
Table 3-15 VGA Vertical Timing Specification
VGA mode
Vertical Timing Spec
Configuration
VGA(60Hz)
VGA(85Hz)
SVGA(60Hz)
SVGA(75Hz)
SVGA(85Hz)
XGA(60Hz)
XGA(70Hz)
XGA(85Hz)
1280x1024(60Hz)
Resolution(HxV)
640x480
640x480
800x600
800x600
800x600
1024x768
1024x768
1024x768
1280x1024
DE1-SoC User Manual
a(lines)
2
3
4
3
3
6
6
3
3
34
b(lines)
33
25
23
21
27
29
29
36
38
c(lines)
480
480
600
600
600
768
768
768
1024
d(lines)
10
1
1
1
1
3
3
1
1
Pixel clock(MHz)
25
36
40
49
56
65
75
95
108
www.terasic.com
April 8, 2015
Table 3-16 Pin Assignment of VGA
Signal Name
VGA_R[0]
VGA_R[1]
VGA_R[2]
VGA_R[3]
VGA_R[4]
VGA_R[5]
VGA_R[6]
VGA_R[7]
VGA_G[0]
VGA_G[1]
VGA_G[2]
VGA_G[3]
VGA_G[4]
VGA_G[5]
VGA_G[6]
VGA_G[7]
VGA_B[0]
VGA_B[1]
VGA_B[2]
VGA_B[3]
VGA_B[4]
VGA_B[5]
VGA_B[6]
VGA_B[7]
VGA_CLK
VGA_BLANK_N
VGA_HS
VGA_VS
VGA_SYNC_N
FPGA Pin No.
PIN_A13
PIN_C13
PIN_E13
PIN_B12
PIN_C12
PIN_D12
PIN_E12
PIN_F13
PIN_J9
PIN_J10
PIN_H12
PIN_G10
PIN_G11
PIN_G12
PIN_F11
PIN_E11
PIN_B13
PIN_G13
PIN_H13
PIN_F14
PIN_H14
PIN_F15
PIN_G15
PIN_J14
PIN_A11
PIN_F10
PIN_B11
PIN_D11
PIN_C10
Description
VGA Red[0]
VGA Red[1]
VGA Red[2]
VGA Red[3]
VGA Red[4]
VGA Red[5]
VGA Red[6]
VGA Red[7]
VGA Green[0]
VGA Green[1]
VGA Green[2]
VGA Green[3]
VGA Green[4]
VGA Green[5]
VGA Green[6]
VGA Green[7]
VGA Blue[0]
VGA Blue[1]
VGA Blue[2]
VGA Blue[3]
VGA Blue[4]
VGA Blue[5]
VGA Blue[6]
VGA Blue[7]
VGA Clock
VGA BLANK
VGA H_SYNC
VGA V_SYNC
VGA SYNC
I/O Standard
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.6.7 TV Decoder
The DE1-SoC board is equipped with an Analog Device ADV7180 TV decoder chip. The
ADV7180 is an integrated video decoder which automatically detects and converts a standard
analog baseband television signals (NTSC, PAL, and SECAM) into 4:2:2 component video data,
which is compatible with the 8-bit ITU-R BT.656 interface standard. The ADV7180 is compatible
with wide range of video devices, including DVD players, tape-based sources, broadcast sources,
and security/surveillance cameras.
DE1-SoC User Manual
35
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April 8, 2015
The registers in the TV decoder can be accessed and set through serial I2C bus by the Cyclone V
SoC FPGA or HPS. Note that the I2C address W/R of the TV decoder (U4) is 0x40/0x41. The pin
assignment of TV decoder is listed in Table 3-17. More information about the ADV7180 is
available on the manufacturer’s website, or in the directory \DE1_SOC_datasheets\Video Decoder
of DE1-SoC System CD.
Figure 3-24 Connections between the FPGA and TV Decoder
Table 3-17 Pin Assignment of TV Decoder
Signal Name
TD_DATA [0]
TD_DATA [1]
TD_DATA [2]
TD_DATA [3]
TD_DATA [4]
TD_DATA [5]
TD_DATA [6]
TD_DATA [7]
TD_HS
TD_VS
TD_CLK27
TD_RESET_N
I2C_SCLK
I2C_SDAT
FPGA Pin No.
PIN_D2
PIN_B1
PIN_E2
PIN_B2
PIN_D1
PIN_E1
PIN_C2
PIN_B3
PIN_A5
PIN_A3
PIN_H15
PIN_F6
PIN_J12 or PIN_E23
PIN_K12 or PIN_C24
DE1-SoC User Manual
Description
TV Decoder Data[0]
TV Decoder Data[1]
TV Decoder Data[2]
TV Decoder Data[3]
TV Decoder Data[4]
TV Decoder Data[5]
TV Decoder Data[6]
TV Decoder Data[7]
TV Decoder H_SYNC
TV Decoder V_SYNC
TV Decoder Clock Input.
TV Decoder Reset
I2C Clock
I2C Data
36
I/O Standard
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
www.terasic.com
April 8, 2015
3.6.8 IR Receiver
The board comes with an infrared remote-control receiver module (model: IRM-V538/TR1), whose
datasheet is provided in the directory \Datasheets\ IR Receiver and Emitter of DE1-SoC system CD.
The remote controller included in the kit has an encoding chip (uPD6121G) built-in for generating
infrared signals. Figure 3-25 shows the connection of IR receiver to the FPGA. Table 3-18 shows
the pin assignment of IR receiver to the FPGA.
Figure 3-25 Connection between the FPGA and IR Receiver
Table 3-18 Pin Assignment of IR Receiver
Signal Name
IRDA_RXD
FPGA Pin No.
PIN_ AA30
Description
IR Receiver
I/O Standard
3.3V
3.6.9 IR Emitter LED
The board has an IR emitter LED for IR communication, which is widely used for operating
television device wirelessly from a short line-of-sight distance. It can also be used to communicate
with other systems by matching this IR emitter LED with another IR receiver on the other side.
Figure 3-26 shows the connection of IR emitter LED to the FPGA. Table 3-19 shows the pin
assignment of IR emitter LED to the FPGA.
DE1-SoC User Manual
37
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April 8, 2015
Figure 3-26 Connection between the FPGA and IR emitter LED
Table 3-19 Pin Assignment of IR Emitter LED
Signal Name
IRDA_TXD
FPGA Pin No.
PIN_ AB30
Description
IR Emitter
I/O Standard
3.3V
3.6.10 SDRAM Memory
The board features 64MB of SDRAM with a single 64MB (32Mx16) SDRAM chip. The chip
consists of 16-bit data line, control line, and address line connected to the FPGA. This chip uses the
3.3V LVCMOS signaling standard. Connections between the FPGA and SDRAM are shown in
Figure 3-27, and the pin assignment is listed in Table 3-20.
DE1-SoC User Manual
38
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April 8, 2015
Figure 3-27 Connections between the FPGA and SDRAM
Table 3-20 Pin Assignment of SDRAM
Signal Name
DRAM_ADDR[0]
DRAM_ADDR[1]
DRAM_ADDR[2]
DRAM_ADDR[3]
DRAM_ADDR[4]
DRAM_ADDR[5]
DRAM_ADDR[6]
DRAM_ADDR[7]
DRAM_ADDR[8]
DRAM_ADDR[9]
DRAM_ADDR[10]
DRAM_ADDR[11]
DRAM_ADDR[12]
DRAM_DQ[0]
DRAM_DQ[1]
DRAM_DQ[2]
DRAM_DQ[3]
DRAM_DQ[4]
DRAM_DQ[5]
FPGA Pin No.
PIN_AK14
PIN_AH14
PIN_AG15
PIN_AE14
PIN_AB15
PIN_AC14
PIN_AD14
PIN_AF15
PIN_AH15
PIN_AG13
PIN_AG12
PIN_AH13
PIN_AJ14
PIN_AK6
PIN_AJ7
PIN_AK7
PIN_AK8
PIN_AK9
PIN_AG10
DE1-SoC User Manual
Description
SDRAM Address[0]
SDRAM Address[1]
SDRAM Address[2]
SDRAM Address[3]
SDRAM Address[4]
SDRAM Address[5]
SDRAM Address[6]
SDRAM Address[7]
SDRAM Address[8]
SDRAM Address[9]
SDRAM Address[10]
SDRAM Address[11]
SDRAM Address[12]
SDRAM Data[0]
SDRAM Data[1]
SDRAM Data[2]
SDRAM Data[3]
SDRAM Data[4]
SDRAM Data[5]
39
I/O Standard
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
www.terasic.com
April 8, 2015
DRAM_DQ[6]
DRAM_DQ[7]
DRAM_DQ[8]
DRAM_DQ[9]
DRAM_DQ[10]
DRAM_DQ[11]
DRAM_DQ[12]
DRAM_DQ[13]
DRAM_DQ[14]
DRAM_DQ[15]
DRAM_BA[0]
DRAM_BA[1]
DRAM_LDQM
DRAM_UDQM
DRAM_RAS_N
DRAM_CAS_N
DRAM_CKE
DRAM_CLK
DRAM_WE_N
DRAM_CS_N
PIN_AK11
PIN_AJ11
PIN_AH10
PIN_AJ10
PIN_AJ9
PIN_AH9
PIN_AH8
PIN_AH7
PIN_AJ6
PIN_AJ5
PIN_AF13
PIN_AJ12
PIN_AB13
PIN_AK12
PIN_AE13
PIN_AF11
PIN_AK13
PIN_AH12
PIN_AA13
PIN_AG11
SDRAM Data[6]
SDRAM Data[7]
SDRAM Data[8]
SDRAM Data[9]
SDRAM Data[10]
SDRAM Data[11]
SDRAM Data[12]
SDRAM Data[13]
SDRAM Data[14]
SDRAM Data[15]
SDRAM Bank Address[0]
SDRAM Bank Address[1]
SDRAM byte Data Mask[0]
SDRAM byte Data Mask[1]
SDRAM Row Address Strobe
SDRAM Column Address Strobe
SDRAM Clock Enable
SDRAM Clock
SDRAM Write Enable
SDRAM Chip Select
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.6.11 PS/2 Serial Port
The DE1-SoC board comes with a standard PS/2 interface and a connector for a PS/2 keyboard or
mouse. Figure 3-28 shows the connection of PS/2 circuit to the FPGA. Users can use the PS/2
keyboard and mouse on the DE1-SoC board simultaneously by a PS/2 Y-Cable, as shown in Figure
3-29. Instructions on how to use PS/2 mouse and/or keyboard can be found on various educational
websites. The pin assignment associated to this interface is shown in Table 3-21.
Note: If users connect only one PS/2 equipment, the PS/2 signals connected to the FPGA I/O
should be “PS2_CLK” and “PS2_DAT”.
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Figure 3-28 Connections between the FPGA and PS/2
Figure 3-29 Y-Cable for using keyboard and mouse simultaneously
Table 3-21 Pin Assignment of PS/2
Signal Name
PS2_CLK
PS2_DAT
PS2_CLK2
PS2_DAT2
FPGA Pin No.
PIN_AD7
PIN_AE7
PIN_AD9
PIN_AE9
DE1-SoC User Manual
Description
PS/2 Clock
PS/2 Data
PS/2 Clock (reserved for second PS/2 device)
PS/2 Data (reserved for second PS/2 device)
41
I/O Standard
3.3V
3.3V
3.3V
3.3V
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3.6.12 A/D Converter and 2x5 Header
The DE1-SoC has an analog-to-digital converter (AD7928), which features lower power,
eight-channel CMOS 12-bit. This ADC offers conversion throughput rate up to 1MSPS. The analog
input range for all input channels can be 0 V to 2.5 V or 0 V to 5V, depending on the RANGE bit in
the control register. It can be configured to accept eight input signals at inputs ADC_IN0 through
ADC_IN7. These eight input signals are connected to a 2x5 header, as shown in Figure 3-30.
More information about the A/D converter chip is available in its datasheet. It can be found on
manufacturer’s website or in the directory \datasheet of De1-SoC system CD.
Figure 3-30 Signals of the 2x5 Header
Figure 3-31 shows the connections between the FPGA, 2x5 header, and the A/D converter.
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Figure 3-31 Connections between the FPGA, 2x5 header, and the A/D converter
Table 3-22 Pin Assignment of ADC
Signal Name
ADC_CS_N
ADC_DOUT
ADC_DIN
ADC_SCLK
FPGA Pin No.
PIN_AJ4
PIN_AK3
PIN_AK4
PIN_AK2
Description
Chip select
Digital data input
Digital data output
Digital clock input
I/O Standard
3.3V
3.3V
3.3V
3.3V
3.7 Peripherals Connected to Hard Processor System (HPS)
This section introduces the interfaces connected to the HPS section of the Cyclone V SoC FPGA.
Users can access these interfaces via the HPS processor.
3.7.1 User Push-buttons and LEDs
Similar to the FPGA, the HPS also has its set of switches, buttons, LEDs, and other interfaces
connected exclusively. Users can control these interfaces to monitor the status of HPS.
Table 3-23 gives the pin assignment of all the LEDs, switches, and push-buttons.
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Table 3-23 Pin Assignment of LEDs, Switches and Push-buttons
Signal Name
HPS_KEY
HPS_LED
HPS GPIO
GPIO54
GPIO53
Register/bit
GPIO1[25]
GPIO1[24]
Function
I/O
I/O
3.7.2 Gigabit Ether net
The board supports Gigabit Ethernet transfer by an external Micrel KSZ9021RN PHY chip and
HPS Ethernet MAC function. The KSZ9021RN chip with integrated 10/100/1000 Mbps Gigabit
Ethernet transceiver also supports RGMII MAC interface. Figure 3-32 shows the connections
between the HPS, Gigabit Ethernet PHY, and RJ-45 connector.
The pin assignment associated to Gigabit Ethernet interface is listed in Table 3-24. More
information about the KSZ9021RN PHY chip and its datasheet, as well as the application notes,
which are available on the manufacturer’s website.
Figure 3-32 Connections between the HPS and Gigabit Ethernet
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Table 3-24 Pin Assignment of Gigabit Ethernet PHY
Signal Name
HPS_ENET_TX_EN
HPS_ENET_TX_DATA[0]
HPS_ENET_TX_DATA[1]
HPS_ENET_TX_DATA[2]
HPS_ENET_TX_DATA[3]
HPS_ENET_RX_DV
HPS_ENET_RX_DATA[0]
HPS_ENET_RX_DATA[1]
HPS_ENET_RX_DATA[2]
HPS_ENET_RX_DATA[3]
HPS_ENET_RX_CLK
HPS_ENET_RESET_N
HPS_ENET_MDIO
HPS_ENET_MDC
HPS_ENET_INT_N
HPS_ENET_GTX_CLK
FPGA Pin No.
PIN_A20
PIN_F20
PIN_J19
PIN_F21
PIN_F19
PIN_K17
PIN_A21
PIN_B20
PIN_B18
PIN_D21
PIN_G20
PIN_E18
PIN_E21
PIN_B21
PIN_C19
PIN_H19
Description
GMII and MII transmit enable
MII transmit data[0]
MII transmit data[1]
MII transmit data[2]
MII transmit data[3]
GMII and MII receive data valid
GMII and MII receive data[0]
GMII and MII receive data[1]
GMII and MII receive data[2]
GMII and MII receive data[3]
GMII and MII receive clock
Hardware Reset Signal
Management Data
Management Data Clock Reference
Interrupt Open Drain Output
GMII Transmit Clock
I/O Standard
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
There are two LEDs, green LED (LEDG) and yellow LED (LEDY), which represent the status of
Ethernet PHY (KSZ9021RNI). The LED control signals are connected to the LEDs on the RJ45
connector. The state and definition of LEDG and LEDY are listed in Table 3-25. For instance, the
connection from board to Gigabit Ethernet is established once the LEDG lights on.
Table 3-25 State and Definition of LED Mode Pins
LED (State)
LEDG
H
L
Toggle
H
H
L
Toggle
LEDY
H
H
H
L
Toggle
L
Toggle
LED (Definition)
Link /Activity
LEDG
OFF
ON
Blinking
OFF
OFF
ON
Blinking
Link off
1000 Link / No Activity
1000 Link / Activity (RX, TX)
100 Link / No Activity
100 Link / Activity (RX, TX)
10 Link/ No Activity
10 Link / Activity (RX, TX)
LEDY
OFF
OFF
OFF
ON
Blinking
ON
Blinking
3.7.3 UART
The board has one UART interface connected for communication with the HPS. This interface
doesn’t support HW flow control signals. The physical interface is implemented by UART-USB
onboard bridge from a FT232R chip to the host with an USB Mini-B connector. More information
about the chip is available on the manufacturer’s website, or in the directory \Datasheets\UART TO
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USB of DE1-SoC system CD. Figure 3-33 shows the connections between the HPS, FT232R chip,
and the USB Mini-B connector. Table 3-26 lists the pin assignment of UART interface connected to
the HPS.
Figure 3-33 Connections between the HPS and FT232R Chip
Table 3-26 Pin Assignment of UART Interface
Signal Name
HPS_UART_RX
HPS_UART_TX
HPS_CONV_USB_N
FPGA Pin No.
PIN_B25
PIN_C25
PIN_B15
Description
HPS UART Receiver
HPS UART Transmitter
Reserve
I/O Standard
3.3V
3.3V
3.3V
3.7.4 DDR3 Memor y
The DDR3 devices connected to the HPS are the exact same model as the ones connected to the
FPGA. The capacity is 1GB and the data bandwidth is in 32-bit, comprised of two x16 devices with
a single address/command bus. The signals are connected to the dedicated Hard Memory Controller
for HPS I/O banks and the target speed is 400 MHz. Table 3-27 lists the pin assignment of DDR3
and its description with I/O standard.
Table 3-27 Pin Assignment of DDR3 Memory
Signal Name
HPS_DDR3_A[0]
HPS_DDR3_A[1]
HPS_DDR3_A[2]
HPS_DDR3_A[3]
HPS_DDR3_A[4]
HPS_DDR3_A[5]
FPGA Pin No.
PIN_F26
PIN_G30
PIN_F28
PIN_F30
PIN_J25
PIN_J27
DE1-SoC User Manual
Description
HPS DDR3 Address[0]
HPS DDR3 Address[1]
HPS DDR3 Address[2]
HPS DDR3 Address[3]
HPS DDR3 Address[4]
HPS DDR3 Address[5]
46
I/O Standard
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
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HPS_DDR3_A[6]
HPS_DDR3_A[7]
HPS_DDR3_A[8]
HPS_DDR3_A[9]
HPS_DDR3_A[10]
HPS_DDR3_A[11]
HPS_DDR3_A[12]
HPS_DDR3_A[13]
HPS_DDR3_A[14]
HPS_DDR3_BA[0]
HPS_DDR3_BA[1]
HPS_DDR3_BA[2]
HPS_DDR3_CAS_n
HPS_DDR3_CKE
HPS_DDR3_CK_n
HPS_DDR3_CK_p
HPS_DDR3_CS_n
HPS_DDR3_DM[0]
HPS_DDR3_DM[1]
HPS_DDR3_DM[2]
HPS_DDR3_DM[3]
HPS_DDR3_DQ[0]
HPS_DDR3_DQ[1]
HPS_DDR3_DQ[2]
HPS_DDR3_DQ[3]
HPS_DDR3_DQ[4]
HPS_DDR3_DQ[5]
HPS_DDR3_DQ[6]
HPS_DDR3_DQ[7]
HPS_DDR3_DQ[8]
HPS_DDR3_DQ[9]
HPS_DDR3_DQ[10]
HPS_DDR3_DQ[11]
HPS_DDR3_DQ[12]
HPS_DDR3_DQ[13]
HPS_DDR3_DQ[14]
HPS_DDR3_DQ[15]
HPS_DDR3_DQ[16]
HPS_DDR3_DQ[17]
HPS_DDR3_DQ[18]
HPS_DDR3_DQ[19]
HPS_DDR3_DQ[20]
HPS_DDR3_DQ[21]
HPS_DDR3_DQ[22]
PIN_F29
PIN_E28
PIN_H27
PIN_G26
PIN_D29
PIN_C30
PIN_B30
PIN_C29
PIN_H25
PIN_E29
PIN_J24
PIN_J23
PIN_E27
PIN_L29
PIN_L23
PIN_M23
PIN_H24
PIN_K28
PIN_M28
PIN_R28
PIN_W30
PIN_K23
PIN_K22
PIN_H30
PIN_G28
PIN_L25
PIN_L24
PIN_J30
PIN_J29
PIN_K26
PIN_L26
PIN_K29
PIN_K27
PIN_M26
PIN_M27
PIN_L28
PIN_M30
PIN_U26
PIN_T26
PIN_N29
PIN_N28
PIN_P26
PIN_P27
PIN_N27
DE1-SoC User Manual
HPS DDR3 Address[6]
HPS DDR3 Address[7]
HPS DDR3 Address[8]
HPS DDR3 Address[9]
HPS DDR3 Address[10]
HPS DDR3 Address[11]
HPS DDR3 Address[12]
HPS DDR3 Address[13]
HPS DDR3 Address[14]
HPS DDR3 Bank Address[0]
HPS DDR3 Bank Address[1]
HPS DDR3 Bank Address[2]
DDR3 Column Address Strobe
HPS DDR3 Clock Enable
HPS DDR3 Clock
HPS DDR3 Clock p
HPS DDR3 Chip Select
HPS DDR3 Data Mask[0]
HPS DDR3 Data Mask[1]
HPS DDR3 Data Mask[2]
HPS DDR3 Data Mask[3]
HPS DDR3 Data[0]
HPS DDR3 Data[1]
HPS DDR3 Data[2]
HPS DDR3 Data[3]
HPS DDR3 Data[4]
HPS DDR3 Data[5]
HPS DDR3 Data[6]
HPS DDR3 Data[7]
HPS DDR3 Data[8]
HPS DDR3 Data[9]
HPS DDR3 Data[10]
HPS DDR3 Data[11]
HPS DDR3 Data[12]
HPS DDR3 Data[13]
HPS DDR3 Data[14]
HPS DDR3 Data[15]
HPS DDR3 Data[16]
HPS DDR3 Data[17]
HPS DDR3 Data[18]
HPS DDR3 Data[19]
HPS DDR3 Data[20]
HPS DDR3 Data[21]
HPS DDR3 Data[22]
47
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SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
Differential 1.5-V SSTL Class I
Differential 1.5-V SSTL Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
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April 8, 2015
HPS_DDR3_DQ[23]
HPS_DDR3_DQ[24]
HPS_DDR3_DQ[25]
HPS_DDR3_DQ[26]
HPS_DDR3_DQ[27]
HPS_DDR3_DQ[28]
HPS_DDR3_DQ[29]
HPS_DDR3_DQ[30]
HPS_DDR3_DQ[31]
HPS_DDR3_DQS_n[0]
HPS_DDR3_DQS_n[1]
HPS_DDR3_DQS_n[2]
HPS_DDR3_DQS_n[3]
HPS_DDR3_DQS_p[0]
HPS_DDR3_DQS_p[1]
HPS_DDR3_DQS_p[2]
HPS_DDR3_DQS_p[3]
HPS_DDR3_ODT
HPS_DDR3_RAS_n
HPS_DDR3_RESET_n
HPS_DDR3_WE_n
HPS_DDR3_RZQ
PIN_R29
PIN_P24
PIN_P25
PIN_T29
PIN_T28
PIN_R27
PIN_R26
PIN_V30
PIN_W29
PIN_M19
PIN_N24
PIN_R18
PIN_R21
PIN_N18
PIN_N25
PIN_R19
PIN_R22
PIN_H28
PIN_D30
PIN_P30
PIN_C28
PIN_D27
HPS DDR3 Data[23]
HPS DDR3 Data[24]
HPS DDR3 Data[25]
HPS DDR3 Data[26]
HPS DDR3 Data[27]
HPS DDR3 Data[28]
HPS DDR3 Data[29]
HPS DDR3 Data[30]
HPS DDR3 Data[31]
HPS DDR3 Data Strobe n[0]
HPS DDR3 Data Strobe n[1]
HPS DDR3 Data Strobe n[2]
HPS DDR3 Data Strobe n[3]
HPS DDR3 Data Strobe p[0]
HPS DDR3 Data Strobe p[1]
HPS DDR3 Data Strobe p[2]
HPS DDR3 Data Strobe p[3]
HPS DDR3 On-die Termination
DDR3 Row Address Strobe
HPS DDR3 Reset
HPS DDR3 Write Enable
External reference ball for
output drive calibration
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
Differential 1.5-V SSTL Class I
Differential 1.5-V SSTL Class I
Differential 1.5-V SSTL Class I
Differential 1.5-V SSTL Class I
Differential 1.5-V SSTL Class I
Differential 1.5-V SSTL Class I
Differential 1.5-V SSTL Class I
Differential 1.5-V SSTL Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
SSTL-15 Class I
1.5 V
3.7.5 Micro SD Card Socket
The board supports Micro SD card interface with x4 data lines. It serves not only an external
storage for the HPS, but also an alternative boot option for DE1-SoC board. Figure 3-34 shows
signals connected between the HPS and Micro SD card socket.
Table 3-28 lists the pin assignment of Micro SD card socket to the HPS.
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Figure 3-34 Connections between the FPGA and SD card socket
Table 3-28 Pin Assignment of Micro SD Card Socket
Signal Name
HPS_SD_CLK
HPS_SD_CMD
HPS_SD_DATA[0]
HPS_SD_DATA[1]
HPS_SD_DATA[2]
HPS_SD_DATA[3]
FPGA Pin No.
PIN_A16
PIN_F18
PIN_G18
PIN_C17
PIN_D17
PIN_B16
Description
HPS SD Clock
HPS SD Command Line
HPS SD Data[0]
HPS SD Data[1]
HPS SD Data[2]
HPS SD Data[3]
I/O Standard
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.7.6 2-por t USB Host
The board has two USB 2.0 type-A ports with a SMSC USB3300 controller and a 2-port hub
controller. The SMSC USB3300 device in 32-pin QFN package interfaces with the SMSC
USB2512B hub controller. This device supports UTMI+ Low Pin Interface (ULPI), which
communicates with the USB 2.0 controller in HPS. The PHY operates in Host mode by connecting
the ID pin of USB3300 to ground. When operating in Host mode, the device is powered by the two
USB type-A ports. Figure 3-35 shows the connections of USB PTG PHY to the HPS. Table 3-29
lists the pin assignment of USBOTG PHY to the HPS.
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Figure 3-35 Connections between the HPS and USB OTG PHY
Table 3-29 Pin Assignment of USB OTG PHY
Signal Name
HPS_USB_CLKOUT
HPS_USB_DATA[0]
HPS_USB_DATA[1]
HPS_USB_DATA[2]
HPS_USB_DATA[3]
HPS_USB_DATA[4]
HPS_USB_DATA[5]
HPS_USB_DATA[6]
HPS_USB_DATA[7]
HPS_USB_DIR
HPS_USB_NXT
HPS_USB_RESET
HPS_USB_STP
FPGA Pin No.
PIN_N16
PIN_E16
PIN_G16
PIN_D16
PIN_D14
PIN_A15
PIN_C14
PIN_D15
PIN_M17
PIN_E14
PIN_A14
PIN_G17
PIN_C15
Description
60MHz Reference Clock Output
HPS USB_DATA[0]
HPS USB_DATA[1]
HPS USB_DATA[2]
HPS USB_DATA[3]
HPS USB_DATA[4]
HPS USB_DATA[5]
HPS USB_DATA[6]
HPS USB_DATA[7]
Direction of the Data Bus
Throttle the Data
HPS USB PHY Reset
Stop Data Stream on the Bus
I/O Standard
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.7.7 G-sensor
The board comes with a digital accelerometer sensor module (ADXL345), commonly known as
G-sensor. This G-sensor is a small, thin, ultralow power assumption 3-axis accelerometer with
high-resolution measurement. Digitalized output is formatted as 16-bit in two’s complement and
can be accessed through I2C interface. The I2C address of G-sensor is 0xA6/0xA7. More
information about this chip can be found in its datasheet, which is available on manufacturer’s
website or in the directory \Datasheet folder of DE1-SoC system CD. Figure 3-36 shows the
connections between the HPS and G-sensor. Table 3-30 lists the pin assignment of G-senor to the
HPS.
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Figure 3-36 Connections between Cyclone V SoC FPGA and G-Sensor
Table 3-30 Pin Assignment of G-senor
Signal Name
HPS_GSENSOR_INT
HPS_I2C1_SCLK
HPS_I2C1_SDAT
FPGA Pin No.
PIN_B22
PIN_E23
PIN_C24
Description
HPS GSENSOR Interrupt Output
HPS I2C Clock (share bus with LTC)
HPS I2C Data (share bus)
I/O Standard
3.3V
3.3V
3.3V
3.7.8 LTC Connector
The board has a 14-pin header, which is originally used to communicate with various daughter
cards from Linear Technology. It is connected to the SPI Master and I2C ports of HPS. The
communication with these two protocols is bi-directional. The 14-pin header can also be used for
GPIO, SPI, or I2C based communication with the HPS. Connections between the HPS and LTC
connector are shown in Figure 3-37, and the pin assignment of LTC connector is listed in Table
3-31.
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Figure 3-37 Connections between the HPS and LTC connector
Table 3-31 Pin Assignment of LTC Connector
Signal Name
HPS_LTC_GPIO
HPS_I2C2_SCLK
FPGA Pin No.
PIN_H17
PIN_H23
HPS_I2C2_SDAT
PIN_A25
HPS_SPIM_CLK
HPS_SPIM_MISO
HPS_SPIM_MOSI
HPS_SPIM_SS
PIN_C23
PIN_E24
PIN_D22
PIN_D24
DE1-SoC User Manual
Description
HPS LTC GPIO
HPS I2C2 Clock (share bus with
G-Sensor)
HPS I2C2 Data (share bus with
G-Sensor)
SPI Clock
SPI Master Input/Slave Output
SPI Master Output /Slave Input
SPI Slave Select
52
I/O Standard
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
3.3V
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April 8, 2015
Chapter 4
DE1-SoC System
Builder
This chapter describes how users can create a custom design project with the tool named DE1-SoC
System Builder.
4.1 Introduction
The DE1-SoC System Builder is a Windows-based utility. It is designed to help users create a
Quartus II project for DE1-SoC within minutes. The generated Quartus II project files include:
Quartus II project file (.qpf)
Quartus II setting file (.qsf)
Top-level design file (.v)
Synopsis design constraints file (.sdc)
Pin assignment document (.htm)
The above files generated by the DE1-SoC System Builder can also prevent occurrence of situations
that are prone to compilation error when users manually edit the top-level design file or place pin
assignment. The common mistakes that users encounter are:
Board is damaged due to incorrect bank voltage setting or pin assignment.
Board is malfunctioned because of wrong device chosen, declaration of pin location or
direction is incorrect or forgotten.
Performance degradation due to improper pin assignment.
4.2 Design Flow
This section provides an introduction to the design flow of building a Quartus II project for
DE1-SoC under the DE1-SoC System Builder. The design flow is illustrated in Figure 4-1.
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The DE1-SoC System Builder will generate two major files, a top-level design file (.v) and a
Quartus II setting file (.qsf) after users launch the DE1-SoC System Builder and create a new
project according to their design requirements
The top-level design file contains a top-level Verilog HDL wrapper for users to add their own
design/logic. The Quartus II setting file contains information such as FPGA device type, top-level
pin assignment, and the I/O standard for each user-defined I/O pin.
Finally, the Quartus II programmer is used to download .sof file to the development board via JTAG
interface.
Figure 4-1 Design flow of building a project from the beginning to the end
4.3 Using DE1-SoC System Builder
This section provides the procedures in details on how to use the DE1-SoC System Builder.
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Install and Launch the DE1-SoC System Builder
The DE1-SoC System Builder is located in the directory: “Tools\SystemBuilder” of the DE1-SoC
System CD. Users can copy the entire folder to a host computer without installing the utility. A
window will pop up, as shown in Figure 4-2, after executing the DE1-SoC SystemBuilder.exe on
the host computer.
Figure 4-2 The GUI of DE1-SoC System Builder
Enter Project Name
Enter the project name in the circled area, as shown in Figure 4-3.
The project name typed in will be assigned automatically as the name of your top-level design
entity.
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Figure 4-3 Enter the project name
System Configuration
Users are given the flexibility in the System Configuration to include their choice of components in
the project, as shown in Figure 4-4. Each component onboard is listed and users can enable or
disable one or more components at will. If a component is enabled, the DE1-SoC System Builder
will automatically generate its associated pin assignment, including the pin name, pin location, pin
direction, and I/O standard.
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Figure 4-4 System configuration group
GPIO Expansion
If users connect any Terasic GPIO-based daughter card to the GPIO connector(s) on DE1-SoC, the
DE1-SoC System Builder can generate a project that include the corresponding module, as shown
in Figure 4-5. It will also generate the associated pin assignment automatically, including pin name,
pin location, pin direction, and I/O standard.
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Figure 4-5 GPIO expansion group
The “Prefix Name” is an optional feature that denote the pin name of the daughter card assigned in
your design. Users may leave this field blank.
Project Setting Management
The DE1-SoC System Builder also provides the option to load a setting or save users’ current board
configuration in .cfg file, as shown in Figure 4-6.
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Figure 4-6 Project Settings
Project Generation
When users press the Generate button, the DE1-SoC System Builder will generate the
corresponding Quartus II files and documents, as listed in Table 4-1:
Table 4-1 Files generated by the DE1-SoC System Builder
No.
1
Filename
.v
Description
Top level Verilog HDL file for Quartus II
2
.qpf
Quartus II Project File
3
.qsf
Quartus II Setting File
4
.sdc
Synopsis Design Constraints file for Quartus II
5
.htm
Pin Assignment Document
Users can add custom logic into the project in Quartus II and compile the project to generate the
SRAM Object File (.sof).
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Chapter 5
Examples For FPGA
This chapter provides examples of advanced designs implemented by RTL or Qsys on the DE1-SoC
board. These reference designs cover the features of peripherals connected to the FPGA, such as
audio, SDRAM, and IR receiver. All the associated files can be found in the directory
\Demonstrations\FPGA of DE1-SoC System CD.
Installation of Demonstrations
To install the demonstrations on your computer:
Copy the folder Demonstrations to a local directory of your choice. It is important to make sure the
path to your local directory contains NO space. Otherwise it will lead to error in Nios II. Note
Quartus II v13.0 or later is required for all DE1-SoC demonstrations to support Cyclone V SoC
device.
5.1 DE1-SoC Factor y Configuration
The DE1-SoC board has a default configuration bit-stream pre-programmed, which demonstrates
some of the basic features onboard. The setup required for this demonstration and the location of its
files are shown below.
Demonstration Setup, File Locations, and Instructions
Project directory: DE1_SoC_Default
Bitstream used: DE1_SoC_Default.sof or DE1_SoC_Default.jic
Power on the DE1-SoC board with the USB cable connected to the USB-Blaster II port. If
necessary (that is, if the default factory configuration is not currently stored in the EPCQ
device), download the bit stream to the board via JTAG interface.
You should now be able to observe the 7-segment displays are showing a sequence of
characters, and the red LEDs are blinking.
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If the VGA D-SUB connector is connected to a VGA display, it would show a color picture.
If the stereo line-out jack is connected to a speaker and KEY[1] is pressed, a 1 kHz humming
sound will come out of the line-out port .
For the ease of execution, a demo_batch folder is provided in the project. It is able to not only
load the bit stream into the FPGA in command line, but also program or erase .jic file to the
EPCQ by executing the test.bat file shown in Figure 5-1.
If users want to program a new design into the EPCQ device, the easiest method is to copy the
new .sof file into the demo_batch folder and execute the test.bat. Option “2” will convert
the .sof to .jic and option”3” will program .jic file into the EPCQ device.
Figure 5-1 Command line of the batch file to program the FPGA and EPCQ device
5.2 Audio Recording and Playing
This demonstration shows how to implement an audio recorder and player on DE1-SoC board with
the built-in audio CODEC chip. It is developed based on Qsys and Eclipse. Figure 5-2 shows the
buttons and slide switches used to interact this demonstration onboard. Users can configure this
audio system through two push-buttons and four slide switches:
SW0 is used to specify the recording source to be Line-in or MIC-In.
SW1, SW2, and SW3 are used to specify the recording sample rate such as 96K, 48K, 44.1K,
32K, or 8K.
Table 5-1 and Table 5-2 summarize the usage of slide switches for configuring the audio
recorder and player.
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Figure 5-2 Buttons and switches for the audio recorder and player
Figure 5-3 shows the block diagram of audio recorder and player design. There are hardware and
software parts in the block diagram. The software part stores the Nios II program in the on-chip
memory. The software part is built under Eclipse in C programming language. The hardware part is
built under Qsys in Quartus II. The hardware part includes all the other blocks such as the “AUDIO
Controller”, which is a user-defined Qsys component and it is designed to send audio data to the
audio chip or receive audio data from the audio chip.
The audio chip is programmed through I2C protocol, which is implemented in C code. The I2C pins
from the audio chip are connected to Qsys system interconnect fabric through PIO controllers. The
audio chip is configured in master mode in this demonstration. The audio interface is configured as
16-bit I2S mode. 18.432MHz clock generated by the PLL is connected to the MCLK/XTI pin of the
audio chip through the audio controller.
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Figure 5-3 Block diagram of the audio recorder and player
Demonstration Setup, File Locations, and Instructions
Hardware project directory: DE1_SoC _Audio
Bitstream used: DE1_SoC_Audio.sof
Software project directory: DE1_SoC _Audio\software
Connect an audio source to the Line-in port
Connect a Microphone to the MIC-in port
Connect a speaker or headset to the Line-out port
Load the bitstream into the FPGA. (note *1)
Load the software execution file into the FPGA. (note *1)
Configure the audio with SW0, as shown in Table 5-1.
Press KEY3 to start/stop audio recording (note *2)
Press KEY2 to start/stop audio playing (note *3)
Table 5-1 Slide switches usage for audio source
Slide Switches
SW0
0 – DOWN Position
Audio is from MIC-in
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1 – UP Position
Audio is from Line-in
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Table 5-2 Settings of switches for the sample rate of audio recorder and player
SW5
SW4
SW3
(0 – DOWN;
(0 – DOWN;
(0 – DOWN;
1- UP)
1-UP)
0
0
0
0
0
1
0
1
1
0
Unlisted combination
1-UP)
0
1
0
1
0
Sample Rate
96K
48K
44.1K
32K
8K
96K
Note:
(1). Execute DE1_SoC _Audio \demo_batch\ DE1-SoC_Audio.bat to download .sof and .elf
files.
(2). Recording process will stop if the audio buffer is full.
(3). Playing process will stop if the audio data is played completely.
5.3 Karaoke Machine
This demonstration uses the microphone-in, line-in, and line-out ports on DE1-SoC to create a
Karaoke machine. The WM8731 CODEC is configured in master mode. The audio CODEC
generates AD/DA serial bit clock (BCK) and the left/right channel clock (LRCK) automatically. The
I2C interface is used to configure the audio CODEC, as shown in Figure 5-4. The sample rate and
gain of the CODEC are set in a similar manner, and the data input from the line-in port is then
mixed with the microphone-in port. The result is sent out to the line-out port.
The sample rate is set to 48 kHz in this demonstration. The gain of the audio CODEC is
reconfigured via I2C bus by pressing the pushbutton KEY0, cycling within ten predefined gain
values (volume levels) provided by the device.
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Figure 5-4 Block diagram of the Karaoke machine demonstration
Demonstration Setup, File Locations, and Instructions
Project directory: DE1_SOC_i2sound
Bitstream used: DE1_SOC_i2sound.sof
Connect a microphone to the microphone-in port (pink color)
Connect the audio output of a music player, such as a MP3 player or computer, to the line-in
port (blue color)
Connect a headset/speaker to the line-out port (green color)
Load the bitstream into the FPGA by executing the batch file ‘DE1_SOC_i2sound’ in the
directory DE1_SOC_i2sound\demo_batch
Users should be able to hear a mixture of microphone sound and the sound from the music
player
Press KEY0 to adjust the volume; it cycles between volume level 0 to 9
Figure 5-5 illustrates the setup for this demonstration.
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Figure 5-5 Setup for the Karaoke machine
5.4 SDRAM Test in Nios II
There are many applications use SDRAM as a temporary storage. Both hardware and software
designs are provided to illustrate how to perform memory access in Qsys in this demonstration. It
also shows how Altera’s SDRAM controller IP accesses SDRAM and how the Nios II processor
reads and writes the SDRAM for hardware verification. The SDRAM controller handles complex
aspects of accessing SDRAM such as initializing the memory device, managing SDRAM banks,
and keeping the devices refreshed at certain interval.
System Block Diagram
Figure 5-6 shows the system block diagram of this demonstration. The system requires a 50 MHz
clock input from the board. The SDRAM controller is configured as a 64MB controller. The
working frequency of the SDRAM controller is 100MHz, and the Nios II program is running on the
on-chip memory.
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Figure 5-6 Block diagram of the SDRAM test in Nios II
The system flow is controlled by a program running in Nios II. The Nios II program writes test
patterns into the entire 64MB of SDRAM first before calling the Nios II system function,
alt_dcache_flush_all, to make sure all the data are written to the SDRAM. It then reads data from
the SDRAM for data verification. The program will show the progress in nios-terminal when
writing/reading data to/from the SDRAM. When the verification process reaches 100%, the result
will be displayed in nios-terminal.
Design Tools
Quartus II v13.1
Nios II Eclipse v13.1
Demonstration Source Code
Quartus project directory: DE1_SoC_SDRAM_Nios_Test
Nios II Eclipse directory: DE1_SoC_SDRAM_Nios_Test \Software
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Nios II Project Compilation
Click “Clean” from the “Project” menu of Nios II Eclipse before compiling the reference
design in Nios II Eclipse.
Demonstration Batch File
The files are located in the directory \DE1_SoC_SDRAM_Nios_Test \demo_batch.
The folder includes the following files:
Batch file for USB-Blaster II : DE1_SoC_SDRAM_Nios_Test.bat and
DE1_SoC_SDRAM_Nios_Test_bashrc
FPGA configuration file : DE1_SoC_SDRAM_Nios_Test.sof
Nios II program: DE1_SoC_SDRAM_Nios_Test.elf
Demonstration Setup
Quartus II v13.1 and Nios II v13.1 must be pre-installed on the host PC.
Power on the DE1-SoC board.
Connect the DE1-SoC board (J13) to the host PC with a USB cable and install the USB-Blaster
driver if necessary.
Execute the demo batch file “DE1_SoC_SDRAM_Nios_Test.bat” from the directory
DE1_SoC_SDRAM_Nios_Test\demo_batch
After the program is downloaded and executed successfully, a prompt message will be
displayed in nios2-terminal.
Press any button (KEY3~KEY0) to start the SDRAM verification process. Press KEY0 to run
the test continuously.
The program will display the test progress and result, as shown in Figure 5-7.
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Figure 5-7 Display of progress and result for the SDRAM test in Nios II
5.5 SDRAM Test in Verilog
DE1-SoC system CD offers another SDRAM test with its test code written in Verilog HDL. The
memory size of the SDRAM bank tested is still 64MB.
Function Block Diagram
Figure 5-8 shows the function block diagram of this demonstration. The SDRAM controller uses 50
MHz as a reference clock and generates 100 MHz as the memory clock.
Figure 5-8 Block diagram of the SDRAM test in Verilog
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RW_test module writes the entire memory with a test sequence first before comparing the data read
back with the regenerated test sequence, which is same as the data written to the memory. KEY0
triggers test control signals for the SDRAM, and the LEDs will indicate the test result according to
Table 5-3.
Design Tools
Quartus II v13.1
Demonstration Source Code
Project directory: DE1_SoC_SDRAM_RTL_Test
Bitstream used: DE1_SoC_SDRAM_RTL_Test.sof
Demonstration Batch File
Demo batch file folder: \DE1_SoC_SDRAM_RTL_Test\demo_batch
The directory includes the following files:
Batch file: DE1_SoC_SDRAM_RTL_Test.bat
FPGA configuration file: DE1_SoC_SDRAM_RTL_Test.sof
Demonstration Setup
Quartus II v13.1 must be pre-installed to the host PC.
Connect the DE1-SoC board (J13) to the host PC with a USB cable and install the USB-Blaster
II driver if necessary
Power on the DE1_SoC board.
Execute the demo batch file “ DE1_SoC_SDRAM_RTL_Test.bat” from the directoy
\DE1_SoC_SDRAM_RTL_Test \demo_batch.
Press KEY0 on the DE1_SoC board to start the verification process. When KEY0 is pressed,
the LEDR [2:0] should turn on. When KEY0 is then released, LEDR1 and LEDR2 should
start blinking.
After approximately 8 seconds, LEDR1 should stop blinking and stay ON to indicate the test is
PASS. Table 5-3 lists the status of LED indicators.
If LEDR2 is not blinking, it means 50MHz clock source is not working.
If LEDR1 failed to remain ON after approximately 8 seconds, the SDRAM test is NG.
Press KEY0 again to repeat the SDRAM test.
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Table 5-3 Status of LED Indicators
Name
LEDR0
LEDR1
Description
Reset
ON if the test is PASS after releasing KEY0
LEDR2
Blinks
5.6 TV Box Demonstration
This demonstration turns DE1-SoC board into a TV box by playing video and audio from a DVD
player using the VGA output, audio CODEC and the TV decoder on the DE1-SoC board. Figure
5-9 shows the block diagram of the design. There are two major blocks in the system called
I2C_AV_Config and TV_to_VGA. The TV_to_VGA block consists of the ITU-R 656 Decoder,
SDRAM Frame Buffer, YUV422 to YUV444, YCbCr to RGB, and VGA Controller. The figure also
shows the TV decoder (ADV7180) and the VGA DAC (ADV7123) chip used.
The register values of the TV decoder are used to configure the TV decoder via the I2C_AV_Config
block, which uses the I2C protocol to communicate with the TV decoder. The TV decoder will be
unstable for a time period upon power up, and the Lock Detector block is responsible for detecting
this instability.
The ITU-R 656 Decoder block extracts YcrCb 4:2:2 (YUV 4:2:2) video signals from the ITU-R 656
data stream sent from the TV decoder. It also generates a data valid control signal, which indicates
the valid period of data output. De-interlacing needs to be performed on the data source because the
video signal for the TV decoder is interlaced. The SDRAM Frame Buffer and a field selection
multiplexer (MUX), which is controlled by the VGA Controller, are used to perform the
de-interlacing operation. The VGA Controller also generates data request and odd/even selection
signals to the SDRAM Frame Buffer and filed selection multiplexer (MUX). The YUV422 to
YUV444 block converts the selected YcrCb 4:2:2 (YUV 4:2:2) video data to the YcrCb 4:4:4 (YUV
4:4:4) video data format.
Finally, the YcrCb_to_RGB block converts the YcrCb data into RGB data output. The VGA
Controller block generates standard VGA synchronous signals VGA_HS and VGA_VS to enable
the display on a VGA monitor.
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Figure 5-9 Block diagram of the TV box demonstration
Demonstration Source Code
Project directory: DE1_SoC_TV
Bitstream used: DE1_SoC_TV.sof
Demonstration Batch File
Demo batch directory: \DE1_SoC_TV \demo_batch
The folder includes the following files:
Batch file: DE1_SoC_TV.bat
FPGA configuration file : DE1_SoC_TV.sof
Demonstration Setup, File Locations, and Instructions
Connect a DVD player’s composite video output (yellow plug) to the Video-in RCA jack (J6)
on the DE1-SoC board, as shown in Figure 5-10. The DVD player has to be configured to
provide:
NTSC output
60Hz refresh rate
4:3 aspect ratio
Non-progressive video
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Connect the VGA output of the DE1-SoC board to a VGA monitor.
Connect the audio output of the DVD player to the line-in port of the DE1-SoC board and
connect a speaker to the line-out port. If the audio output jacks from the DVD player are RCA
type, an adaptor is needed to convert to the mini-stereo plug supported on the DE1-SoC
board.
Load the bitstream into the FPGA by executing the batch file ‘DE1_SoC_TV.bat’ from the
directory \DE1_SoC_TV \demo_batch\. Press KEY0 on the DE1-SoC board to reset the
demonstration.
Figure 5-10 Setup for the TV box demonstration
5.7 PS/2 Mouse Demonstration
A simply PS/2 controller coded in Verilog HDL is provided to demonstrate bi-directional
communication with a PS/2 mouse. A comprehensive PS/2 controller can be developed based on it
and more sophisticated functions can be implemented such as setting the sampling rate or resolution,
which needs to transfer two data bytes at once.
More information about the PS/2 protocol can be found on various websites.
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Introduction
PS/2 protocol uses two wires for bi-directional communication. One is the clock line and the other
one is the data line. The PS/2 controller always has total control over the transmission line, but it is
the PS/2 device which generates the clock signal during data transmission.
Data Transmission from Device to the Controller
After the PS/2 mouse receives an enabling signal at stream mode, it will start sending out
displacement data, which consists of 33 bits. The frame data is cut into three sections and each of
them contains a start bit (always zero), eight data bits (with LSB first), one parity check bit (odd
check), and one stop bit (always one).
The PS/2 controller samples the data line at the falling edge of the PS/2 clock signal. This is
implemented by a shift register, which consists of 33 bits.
easily be implemented using a shift register of 33 bits, but be cautious with the clock domain
crossing problem.
Data Transmission from the Controller to Device
When the PS/2 controller wants to transmit data to device, it first pulls the clock line low for more
than one clock cycle to inhibit the current transmission process or to indicate the start of a new
transmission process, which is usually called as inhibit state. It then pulls low the data line before
releasing the clock line. This is called the request state. The rising edge on the clock line formed by
the release action can also be used to indicate the sample time point as for a 'start bit. The device
will detect this succession and generates a clock sequence in less than 10ms time. The transmit data
consists of 12bits, one start bit (as explained before), eight data bits, one parity check bit (odd
check), one stop bit (always one), and one acknowledge bit (always zero). After sending out the
parity check bit, the controller should release the data line, and the device will detect any state
change on the data line in the next clock cycle. If there’s no change on the data line for one clock
cycle, the device will pull low the data line again as an acknowledgement which means that the data
is correctly received.
After the power on cycle of the PS/2 mouse, it enters into stream mode automatically and disable
data transmit unless an enabling instruction is received. Figure 5-11 shows the waveform while
communication happening on two lines.
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Figure 5-11 Waveform of clock and data signals during data transmission
Demonstration Source Code
Project directory: DE1_SoC_PS2_DEMO
Bitstream used: DE1_SoC_PS2_DEMO.sof
Demonstration Batch File
Demo batch file directoy: \DE1_SoC_PS2_DEMO \demo_batch
The folder includes the following files:
Batch file: DE1_SoC_PS2_DEMO.bat
FPGA configuration file : DE1_SoC_PS2_DEMO.sof
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Demonstration Setup, File Locations, and Instructions
Load the bitstream into the FPGA by executing \DE1_SoC_PS2_DEMO \demo_batch\
DE1_SoC_PS2_DEMO.bat
Plug in the PS/2 mouse
Press KEY[0] to enable data transfer
Press KEY[1] to clear the display data cache
The 7-segment display should change when the PS/2 mouse moves. The LEDR[2:0] will blink
according to Table 5-4 when the left-button, right-button, and/or middle-button is pressed.
Table 5-4 Description of 7-segment Display and LED Indicators
Indicator Name
LEDR[0]
LEDR[1]
LEDR[2]
HEX0
HEX1
HEX2
HEX3
Description
Left button press indicator
Right button press indicator
Middle button press indicator
Low byte of X displacement
High byte of X displacement
Low byte of Y displacement
High byte of Y displacement
5.8 IR Emitter LED and Receiver Demonstration
DE1-SoC system CD has an example of using the IR Emitter LED and IR receiver. This
demonstration is coded in Verilog HDL.
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Figure 5-12 Block diagram of the IR emitter LED and receiver demonstration
Figure 5-12 shows the block diagram of the design. It implements a IR TX Controller and a IR RX
Controller. When KEY0 is pressed, data test pattern generator will generate data to the IR TX
Controller continuously. When IR TX Controller is active, it will format the data to be compatible
with NEC IR transmission protocol and send it out through the IR emitter LED. The IR receiver
will decode the received data and display it on the six HEXs. Users can also use a remote to send
data to the IR Receiver. The main function of IR TX /RX controller and IR remote in this
demonstration is described in the following sections.
IR TX Controller
Users can input 8-bit address and 8-bit command into the IR TX Controller. The IR TX Controller will
encode the address and command first before sending it out according to NEC IR transmission protocol
through the IR emitter LED. The input clock of IR TX Controller should be 50MHz.
The NEC IR transmission protocol uses pulse distance to encode the message bits. Each pulse burst is
562.5µs in length with a carrier frequency of 38kHz (26.3µs).
Figure 5-13 shows the duration of logical “1” and “0”. Logical bits are transmitted as follows:
•
Logical '0' – a 562.5µs pulse burst followed by a 562.5µs space with a total transmit time
of 1.125ms
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•
Logical '1' – a 562.5µs pulse burst followed by a 1.6875ms space with a total transmit time
of 2.25ms
Figure 5-13 Duration of logical “1”and logical “0”
Figure 5-14 shows a frame of the protocol. Protocol sends a lead code first, which is a 9ms leading
pulse burst, followed by a 4.5ms window. The second inversed data is sent to verify the accuracy of the
information received. A final 562.5µs pulse burst is sent to signify the end of message transmission.
Because the data is sent in pair (original and inverted) according to the protocol, the overall
transmission time is constant.
Figure 5-14 Typical frame of NEC protocol
Note: The signal received by IR Receiver is inverted. For instance, if IR TX Controller sends a lead
code 9 ms high and then 4.5 ms low, IR Receiver will receive a 9 ms low and then 4.5 ms high lead
code.
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IR Remote
When a key on the remote controller show in Figure 5-15 is pressed, the remote controller will emit
a standard frame, as shown in Table 5-5. The beginning of the frame is the lead code, which
represents the start bit, followed by the key-related information. The last bit end code represents the
end of the frame. The value of this frame is completely inverted at the receiving end.
Figure 5-15 The remote controller used in this demonstration
Table 5-5 Key Code Information for Each Key on the Remote
Key
Key Code
Key
Key Code
Key
Key Code
Key
Key Code
0x0F
0x13
0x10
0x12
0x01
0x02
0x03
0x1A
0x04
0x05
0x06
0x1E
0x07
0x08
0x09
0x1B
0x11
0x00
0x17
0x1F
0x16
0x14
0x18
0x0C
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Lead Code 1bit
Custom Code 16bits Key Code 8bits
Inv Key Code
8bits
End
Code
1bit
Figure 5-16 The transmitting frame of the IR remote controller
IR RX Controller
The following demonstration shows how to implement the IP of IR receiver controller in the FPGA.
Figure 5-17 shows the modules used in this demo, including Code Detector, State Machine, and
Shift Register. At the beginning the IR receiver demodulates the signal inputs to the Code Detector .
The Code Detector will check the Lead Code and feedback the examination result to the State
Machine.
The State Machine block will change the state from IDLE to GUIDANCE once the Lead Code is
detected. If the Code Detector detects the Custom Code status, the current state will change from
GUIDANCE to DATAREAD state. The Code Detector will also save the receiving data and output
to the Shift Register and display on the 7-segment. Figure 5-18 shows the state shift diagram of
State Machine block. The input clock should be 50MHz.
Figure 5-17 Modules in the IR Receiver controller
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Figure 5-18 State shift diagram of State Machine block
Demonstration Source Code
Project directory: DE1_SoC_IR
Bitstream used:
DE1_SOC_IR.sof
Demonstration Batch File
Demo batch file directory: DE1_SoC_IR \demo_batch
The folder includes the following files:
Batch file: DE1_SoC_IR.bat
FPGA configuration file : DE1_SOC_IR.sof
Demonstration Setup, File Locations, and Instructions
Load the bitstream into the FPGA by executing DE1_SoC_IR \demo_batch\ DE1_SoC_IR.bat
Keep pressing KEY[0] to enable the pattern to be sent out continuously by the IR TX
Controller.
Observe the six HEXs according to Table 5-6
Release KEY[0] to stop the IR TX.
Point the IR receiver with the remote and press any button
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Observe the six HEXs according to Table 5-6
Table 5-6 Detailed Information of the Indicators
Indicator Name
HEX5
HEX4
HEX3
HEX2
HEX1
HEX0
Description
Inversed high byte of DATA(Key Code)
Inversed low byte of DATA(Key Code)
High byte of ADDRESS(Custom Code)
Low byte of ADDRESS(Custom Code)
High byte of DATA(Key Code)
Low byte of DATA (Key Code)
5.9 ADC Reading
This demonstration illustrates steps to evaluate the performance of the 8-channel 12-bit A/D
Converter ADC7928. The DC 5.0V on the 2x5 header is used to drive the analog signals by a
trimmer potentiometer. The voltage can be adjusted within the range between 0 and 5.0V. The 12-bit
voltage measurement is displayed on the NIOS II console. Figure 5-19 shows the block diagram of
this demonstration.
If the input voltage is -2.5V ~ 2.5V, a pre-scale circuit can be used to adjust it to 0 ~ 5V.
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Figure 5-19 Block diagram of ADC reading
Figure 5-20 depicts the pin arrangement of the 2x5 header. This header is the input source of ADC
convertor in this demonstration. Users can connect a trimmer to the specified ADC channel
(ADC_IN0 ~ ADC_IN7) that provides voltage to the ADC convert. The FPGA will read the
associated register in the convertor via serial interface and translates it to voltage value to be
displayed on the Nios II console.
Figure 5-20 Pin distribution of the 2x5 Header for the ADC
System Requirements
The following items are required for this demonstration.
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DE1-SoC board x1
Trimmer Potentiometer x1
Wire Strip x3
Demonstration File Locations
Hardware project directory: DE1_SoC_ADC
Bitstream used: DE1_SoC_ADC.sof
Software project directory: DE1_SoC_ADC software
Demo batch file : DE1_SoC_ADC\demo_batch\ DE1_SoC_ADC.bat
Demonstration Setup and Instructions
Connect the trimmer to corresponding ADC channel on the 2x5 header, as shown in Figure
5-21, as well as the +5V and GND signals. The setup shown above is connected to ADC
channel 0.
Execute the demo batch file DE1_SoC_ADC.bat to load the bitstream and software execution
file to the FPGA.
The Nios II console will display the voltage of the specified channel voltage result information
Figure 5-21 Hardware setup for the ADC reading demonstration
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Chapter 6
Examples for HPS
SoC
This chapter provides several C-code examples based on the Altera SoC Linux built by Yocto
project. These examples demonstrates major features connected to HPS interface on DE1-SoC
board such as users LED/KEY, I2C interfaced G-sensor, and I2C MUX. All the associated files can
be found in the directory Demonstrations/SOC of the DE1_SoC System CD. Please refer to Chapter
5 "Running Linux on the DE1-SoC board" from the DE1-SoC_Getting_Started_Guide.pdf to run
Linux on DE1-SoC board.
Installation of the Demonstrations
To install the demonstrations on the host computer:
Copy the directory Demonstrations into a local directory of your choice. Altera SoC EDS v13.1 is
required for users to compile the c-code project.
6.1 Hello Program
This demonstration shows how to develop first HPS program with Altera SoC EDS tool. Please
refer to My_First_HPS.pdf from the system CD for more details.
The major procedures to develop and build HPS project are:
Install Altera SoC EDS on the host PC.
Create program .c/.h files with a generic text editor
Create a "Makefile" with a generic text editor
Build the project under Altera SoC EDS
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Program File
The main program for the Hello World demonstration is:
Makefile
A Makefile is required to compile a project. The Makefile used for this demo is:
Compile
Please launch Altera SoC EDS Command Shell to compile a project by executing
C:\altera\13.1\embedded\Embedded_Command_Shell.bat
The "cd" command can change the current directory to where the Hello World project is located.
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The "make" command will build the project. The executable file "my_first_hps" will be generated
after the compiling process is successful. The "clean all" command removes all temporary files.
Demonstration Source Code
Build tool: Altera SoC EDS v13.1
Project directory: \Demonstration\SoC\my_first_hps
Binary file: my_first_hps
Build command: make ("make clean" to remove all temporary files)
Execute command: ./my_first_hps
Demonstration Setup
Connect a USB cable to the USB-to-UART connector (J4) on the DE1-SoC board and the host
PC.
Copy the demo file "my_first_hps" into a microSD card under the "/home/root" folder in
Linux.
Insert the booting microSD card into the DE1-SoC board.
Power on the DE1-SoC board.
Launch PuTTY and establish connection to the UART port of Putty. Type "root" to login Altera
Yocto Linux.
Type "./my_first_hps" in the UART terminal of PuTTY to start the program, and the "Hello
World!" message will be displayed in the terminal.
6.2 Users LED and KEY
This demonstration shows how to control the users LED and KEY by accessing the register of
GPIO controller through the memory-mapped device driver. The memory-mapped device driver
allows developer to access the system physical memory.
Function Block Diagram
Figure 6-1 shows the function block diagram of this demonstration. The users LED and KEY are
connected to the GPIO1 controller in HPS. The behavior of GPIO controller is controlled by the
register in GPIO controller. The registers can be accessed by application software through the
memory-mapped device driver, which is built into Altera SoC Linux.
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Figure 6-1 Block diagram of GPIO demonstration
Block Diagram of GPIO Interface
The HPS provides three general-purpose I/O (GPIO) interface modules. Figure 6-2 shows the block
diagram of GPIO Interface. GPIO[28..0] is controlled by the GPIO0 controller and GPIO[57..29] is
controlled by the GPIO1 controller. GPIO[70..58] and input-only GPI[13..0] are controlled by the
GPIO2 controller.
Figure 6-2 Block diagram of GPIO Interface
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GPIO Register Block
The behavior of I/O pin is controlled by the registers in the register block. There are three 32-bit
registers in the GPIO controller used in this demonstration. The registers are:
gpio_swporta_dr: write output data to output I/O pin
gpio_swporta_ddr: configure the direction of I/O pin
gpio_ext_porta: read input data of I/O input pin
The gpio_swporta_ddr configures the LED pin as output pin and drives it high or low by writing
data to the gpio_swporta_dr register. The first bit (least significant bit) of gpio_swporta_dr
controls the direction of first IO pin in the associated GPIO controller and the second bit controls
the direction of second IO pin in the associated GPIO controller and so on. The value "1" in the
register bit indicates the I/O direction is output, and the value "0" in the register bit indicates the I/O
direction is input.
The first bit of gpio_swporta_dr register controls the output value of first I/O pin in the associated
GPIO controller, and the second bit controls the output value of second I/O pin in the associated
GPIO controller and so on. The value "1" in the register bit indicates the output value is high, and
the value "0" indicates the output value is low.
The status of KEY can be queried by reading the value of gpio_ext_porta register. The first bit
represents the input status of first IO pin in the associated GPIO controller, and the second bit
represents the input status of second IO pin in the associated GPIO controller and so on. The value
"1" in the register bit indicates the input state is high, and the value "0" indicates the input state is
low.
GPIO Register Address Mapping
The registers of HPS peripherals are mapped to HPS base address space 0xFC000000 with 64KB
size. The registers of the GPIO1 controller are mapped to the base address 0xFF708000 with 4KB
size, and the registers of the GPIO2 controller are mapped to the base address 0xFF70A000 with
4KB size, as shown in Figure 6-3.
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Figure 6-3 GPIO address map
Software API
Developers can use the following software API to access the register of GPIO controller.
open: open memory mapped device driver
mmap: map physical memory to user space
alt_read_word: read a value from a specified register
alt_write_word: write a value into a specified register
munmap: clean up memory mapping
close: close device driver.
Developers can also use the following MACRO to access the register
alt_setbits_word: set specified bit value to one for a specified register
alt_clrbits_word: set specified bit value to zero for a specified register
The program must include the following header files to use the above API to access the registers of
GPIO controller.
#include
#include
#include
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#include
#include "hwlib.h"
#include "socal/socal.h"
#include "socal/hps.h"
#include "socal/alt_gpio.h"
LED and KEY Control
Figure 6-4 shows the HPS users LED and KEY pin assignment for the DE1_SoC board. The LED
is connected to HPS_GPIO53 and the KEY is connected to HPS_GPIO54. They are controlled by
the GPIO1 controller, which also controls HPS_GPIO29 ~ HPS_GPIO57.
Figure 6-4 Pin assignment of LED and KEY
Figure 6-5 shows the gpio_swporta_ddr register of the GPIO1 controller. The bit-0 controls the
pin direction of HPS_GPIO29. The bit-24 controls the pin direction of HPS_GPIO53, which
connects to HPS_LED, the bit-25 controls the pin direction of HPS_GPIO54, which connects to
HPS_KEY and so on. The pin direction of HPS_LED and HPS_KEY are controlled by the bit-24
and bit-25 in the gpio_swporta_ddr register of the GPIO1 controller, respectively. Similarly, the
output status of HPS_LED is controlled by the bit-24 in the gpio_swporta_dr register of the
GPIO1 controller. The status of KEY can be queried by reading the value of the bit-24 in the
gpio_ext_porta register of the GPIO1 controller.
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Figure 6-5 gpio_swporta_ddr register in the GPIO1 controller
The following mask is defined in the demo code to control LED and KEY direction and LED’s
output value.
#define USER_IO_DIR
(0x01000000)
#define BIT_LED
(0x01000000)
#define BUTTON_MASK
(0x02000000)
The following statement is used to configure the LED associated pins as output pins.
alt_setbits_word( ( virtual_base +
( ( uint32_t )( ALT_GPIO1_SWPORTA_DDR_ADDR ) &
( uint32_t )( HW_REGS_MASK ) ) ), USER_IO_DIR );
The following statement is used to turn on the LED.
alt_setbits_word( ( virtual_base +
( ( uint32_t )( ALT_GPIO1_SWPORTA_DR_ADDR ) &
( uint32_t )( HW_REGS_MASK ) ) ), BIT_LED );
The following statement is used to read the content of gpio_ext_porta register. The bit mask is used
to check the status of the key.
alt_read_word( ( virtual_base +
( ( uint32_t )( ALT_GPIO1_EXT_PORTA_ADDR ) &
( uint32_t )( HW_REGS_MASK ) ) ) );
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Demonstration Source Code
Build tool: Altera SoC EDS V13.1
Project directory: \Demonstration\SoC\hps_gpio
Binary file: hps_gpio
Build command: make ('make clean' to remove all temporal files)
Execute command: ./hps_gpio
Demonstration Setup
Connect a USB cable to the USB-to-UART connector (J4) on the DE1-SoC board and the host
PC.
Copy the executable file "hps_gpio" into the microSD card under the "/home/root" folder in
Linux.
Insert the booting micro SD card into the DE1-SoC board.
Power on the DE1-SoC board.
Launch PuTTY and establish connection to the UART port of Putty. Type "root" to login Altera
Yocto Linux.
Type "./hps_gpio " in the UART terminal of PuTTY to start the program.
HPS_LED will flash twice and users can control the user LED with push-button.
Press HPS_KEY to light up HPS_LED.
Press "CTRL + C" to terminate the application.
6.3 I2C Interfaced G-sensor
This demonstration shows how to control the G-sensor by accessing its registers through the built-in
I2C kernel driver in Altera Soc Yocto Powered Embedded Linux.
Function Block Diagram
Figure 6-6 shows the function block diagram of this demonstration. The G-sensor on the DE1_SoC
board is connected to the I2C0 controller in HPS. The G-Sensor I2C 7-bit device address is 0x53.
The system I2C bus driver is used to access the register files in the G-sensor. The G-sensor interrupt
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signal is connected to the PIO controller. This demonstration uses polling method to read the
register data.
Figure 6-6 Block diagram of the G-sensor demonstration
I2C Driver
The procedures to read a register value from G-sensor register files by the existing I2C bus driver in
the system are:
1. Open I2C bus driver "/dev/i2c-0": file = open("/dev/i2c-0", O_RDWR);
2. Specify G-sensor's I2C address 0x53: ioctl(file, I2C_SLAVE, 0x53);
3. Specify desired register index in g-sensor: write(file, &Addr8, sizeof(unsigned char));
4. Read one-byte register value: read(file, &Data8, sizeof(unsigned char));
The G-sensor I2C bus is connected to the I2C0 controller, as shown in the Figure 6-7. The driver
name given is '/dev/i2c-0'.
Figure 6-7 Connection of HPS I2C signals
The step 4 above can be changed to the following to write a value into a register.
write(file, &Data8, sizeof(unsigned char));
The step 4 above can also be changed to the following to read multiple byte values.
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read(file, &szData8, sizeof(szData8)); // where szData is an array of bytes
The step 4 above can be changed to the following to write multiple byte values.
write(file, &szData8, sizeof(szData8)); // where szData is an array of bytes
G-sensor Control
The ADI ADXL345 provides I2C and SPI interfaces. I2C interface is selected by setting the CS pin
to high on the DE1_SoC board.
The ADI ADXL345 G-sensor provides user-selectable resolution up to 13-bit ± 16g. The
resolution can be configured through the DATA_FORAMT(0x31) register. The data format in this
demonstration is configured as:
Full resolution mode
± 16g range mode
Left-justified mode
The X/Y/Z data value can be derived from the DATAX0(0x32), DATAX1(0x33), DATAY0(0x34),
DATAY1(0x35), DATAZ0(0x36), and DATAX1(0x37) registers. The DATAX0 represents the least
significant byte and the DATAX1 represents the most significant byte. It is recommended to
perform multiple-byte read of all registers to prevent change in data between sequential registers
read. The following statement reads 6 bytes of X, Y, or Z value.
read(file, szData8, sizeof(szData8)); // where szData is an array of six-bytes
Demonstration Source Code
Build tool: Altera SoC EDS v13.1
Project directory: \Demonstration\SoC\hps_gsensor
Binary file: gsensor
Build command: make ('make clean' to remove all temporal files)
Execute command: ./gsensor [loop count]
Demonstration Setup
Connect a USB cable to the USB-to-UART connector (J4) on the DE1-SoC board and the host
PC.
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Copy the executable file "gsensor" into the microSD card under the "/home/root" folder in
Linux.
Insert the booting microSD card into the DE1-SoC board.
Power on the DE1-SoC board.
Launch PuTTY to establish connection to the UART port of DE1-SoC board. Type "root" to
login Yocto Linux.
Execute "./gsensor" in the UART terminal of PuTTY to start the G-sensor polling.
The demo program will show the X, Y, and Z values in the PuTTY, as shown in Figure 6-8.
Figure 6-8 Terminal output of the G-sensor demonstration
Press "CTRL + C" to terminate the program.
6.4 I2C MUX Test
The I2C bus on DE1-SoC is originally accessed by FPGA only. This demonstration shows how to
switch the I2C multiplexer for HPS to access the I2C bus.
Function Block Diagram
Figure 6-9 shows the function block diagram of this demonstration. The I2C bus from both FPGA
and HPS are connected to an I2C multiplexer. It is controlled by HPS_I2C_CONTROL, which is
connected to the GPIO1 controller in HPS. The HPS I2C is connected to the I2C0 controller in
HPS, as well as the G-sensor.
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Figure 6-9 Block diagram of the I2C MUX test demonstration
HPS_I2C_CONTROL Control
HPS_I2C_CONTROL is connected to HPS_GPIO48, which is bit-19 of the GPIO1 controller.
Once HPS gets access to the I2C bus, it can then access Audio CODEC and TV Decoder when the
HPS_I2C_CONTROL signal is set to high.
The following mask in the demo code is defined to control the direction and output value of
HPS_I2C_CONTROL.
#define HPS_I2C_CONTROL
( 0x00080000 )
The following statement is used to configure the HPS_I2C_CONTROL associated pins as output
pin.
alt_setbits_word( ( virtual_base +
( ( uint32_t )( ALT_GPIO1_SWPORTA_DDR_ADDR ) &
( uint32_t )( HW_REGS_MASK ) ) ), HPS_I2C_CONTROL );
The following statement is used to set HPS_I2C_CONTROL high.
alt_setbits_word( ( virtual_base +
( ( uint32_t )( ALT_GPIO1_SWPORTA_DR_ADDR ) &
( uint32_t )( HW_REGS_MASK ) ) ), HPS_I2C_CONTROL );
The following statement is used to set HPS_I2C_CONTROL low.
alt_clrbits_word( ( virtual_base +
( ( uint32_t )( ALT_GPIO1_SWPORTA_DR_ADDR ) &
( uint32_t )( HW_REGS_MASK ) ) ), HPS_I2C_CONTROL );
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I2C Driver
The procedures to read register value from TV Decoder by the existing I2C bus driver in the system
are:
Set HPS_I2C_CONTROL high for HPS to access I2C bus.
Open the I2C bus driver "/dev/i2c-0": file = open("/dev/i2c-0", O_RDWR);
Specify the I2C address 0x20 of ADV7180: ioctl(file, I2C_SLAVE, 0x20);
Read or write registers;
Set HPS_I2C_CONTROL low to release the I2C bus.
Demonstration Source Code
Build tool: Altera SoC EDS v13.1
Project directory: \Demonstration\SoC\ hps_i2c_switch
Binary file: i2c_switch
Build command: make ('make clean' to remove all temporal files)
Execute command: ./ i2c_switch
Demonstration Setup
Connect a USB cable to the USB-to-UART connector (J4) on the DE1-SoC board and host PC.
Copy the executable file " i2c_switch " into the microSD card under the "/home/root" folder in
Linux.
Insert the booting microSD card into the DE1-SoC board.
Power on the DE1-SoC board.
Launch PuTTY to establish connection to the UART port of DE1_SoC borad. Type "root" to
login Yocto Linux.
Execute "./ i2c_switch " in the UART terminal of PuTTY to start the I2C MUX test.
The demo program will show the result in the Putty, as shown in Figure 6-10.
Figure 6-10 Terminal output of the I2C MUX Test Demonstration
Press "CTRL + C" to terminate the program.
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Chapter 7
Examples for using
both HPS SoC and
FGPA
Although HPS and FPGA can operate independently, they are tightly coupled via a high-bandwidth
system interconnect built from high-performance ARM AMBA® AXITM bus bridges. Both FPGA
fabric and HPS can access to each other via these interconnect bridges. This chapter provides
demonstrations on how to achieve superior performance and lower latency through these
interconnect bridges when comparing to solutions containing a separate FPGA and discrete
processor.
7.1 HPS Control LED and HEX
This demonstration shows how HPS controls the FPGA LED and HEX through Lightweight
HPS-to-FPGA Bridge. The FPGA is configured by HPS through FPGA manager in HPS.
A brief view on FPGA manager
The FPGA manager in HPS configures the FPGA fabric from HPS. It also monitors the state of
FPGA and drives or samples signals to or from the FPGA fabric. The application software is
provided to configure FPGA through the FPGA manager. The FPGA configuration data is stored in
the file with .rbf extension. The MSEL[4:0] must be set to 01010 or 01110 before executing the
application software on HPS.
Function Block Diagram
Figure 7-1 shows the block diagram of this demonstration. The HPS uses Lightweight
HPS-to-FPGA AXI Bridge to communicate with FPGA. The hardware in FPGA part is built into
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Qsys. The data transferred through Lightweight HPS-to-FPGA Bridge is converted into Avalon-MM
master interface. Both PIO Controller and HEX Controller work as Avalon-MM slave in the system.
They control the associated pins to change the state of LED and HEX. This is similar to a system
using Nios II processor to control LED and HEX.
Figure 7-1 FPGA LED and HEX are controlled by HPS
LED and HEX control
The Lightweight HPS-to-FPGA Bridge is a peripheral of HPS. The software running on Linux
cannot access the physical address of the HPS peripheral. The physical address must be mapped to
the user space before the peripheral can be accessed. Alternatively, a customized device driver
module can be added to the kernel. The entire CSR span of HPS is mapped to access various
registers within that span. The mapping function and the macro defined below can be reused if any
other peripherals whose physical address is also in this span.
The start address of Lightweight HPS-to-FPGA Bridge after mapping can be retrieved by
ALT_LWFPGASLVS_OFST, which is defined in altera_hps hardware library. The slave IP
connected to the bridge can then be accessed through the base address and the register offset in
these IPs. For instance, the base address of the PIO slave IP in this system is 0x0001_0040, the
direction control register offset is 0x01, and the data register offset is 0x00. The following statement
is used to retrieve the base address of PIO slave IP.
h2p_lw_led_addr=virtual_base+( ( unsigned long )( ALT_LWFPGASLVS_OFST
+ LED_PIO_BASE ) & ( unsigned long)( HW_REGS_MASK ) );
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Considering this demonstration only needs to set the direction of PIO as output, which is the default
direction of the PIO IP, the step above can be skipped. The following statement is used to set the
output state of the PIO.
alt_write_word(h2p_lw_led_addr, Mask );
The Mask in the statement decides which bit in the data register of the PIO IP is high or low. The
bits in data register decide the output state of the pins connected to the LEDs. The HEX controlling
part is similar to the LED.
Since Linux supports multi-thread software, the software for this system creates two threads. One
controls the LED and the other one controls the HEX. The system calls pthread_create, which is
called in the main function to create a sub-thread, to complete the job. The program running in the
sub-thread controls the LED flashing in a loop. The main-thread in the main function controls the
digital shown on the HEX that keeps changing in a loop. The state of LED and HEX state change
simultaneously when the FPGA is configured and the software is running on HPS.
Demonstration Source Code
Build tool: Altera SoC EDS V13.1
Project directory: \Demonstration\ SoC_FPGA\HPS_LED_HEX
Quick file directory:\ Demonstration\ SoC_FPGA\HPS_LED_HEX\ quickfile
FPGA configuration file : soc_system_dc.rbf
Binary file: HPS_LED_HEX and hps_config_fpga
Build app command: make ('make clean' to remove all temporal files)
Execute app command:./hps_config_fpga soc_system_dc.rbf and./HPS_LED_HEX
Demonstration Setup
Quartus II and Nios II must be installed on the host PC.
The MSEL[4:0] is set to 01010 or 01110.
Connect a USB cable to the USB-Blaster II connector (J13) on the DE1-SoC board and the host
PC. Install the USB-Blaster II driver if necessary.
Connect a USB cable to the USB-to-UART connector (J4) on the DE1-SoC board and the host
PC.
Copy the executable files "hps_config_fpga" and "HPS_LED_HEX", and the FPGA
configuration file "soc_system_dc.rbf" into the microSD card under the "/home/root" folder
in Linux.
Insert the booting microSD card into the DE1-SoC board. Please refer to the chapter 5
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"Running Linux on the DE1-SoC board" on DE1-SoC_Getting_Started_Guide.pdf on how to
build a booting microSD card image.
Power on the DE1-SoC board.
Launch PuTTY to establish connection to the UART port of the DE1-SoC board. Type "root"
to login Altera Yocto Linux.
Execute "./hps_config_fpga soc_system_dc.rbf " in the UART terminal of PuTTY to configure
the FPGA through the FPGA manager. After the configuration is successful, the message
shown in Figure 7-2Figure72 will be displayed in the terminal.
Figure 7-2 Running the application to configure the FPGA
Execute "./HPS_LED_HEX " in the UART terminal of PuTTY to start the program.
The message shown in Figure 7-3OLE_LINK4, will be displayed in the terminal. The LED[9:0]
will be flashing and the number on the HEX[5:0] will keep changing simultaneously.
Figure 7-3 Running result in the terminal of PuTTY
Press "CTRL + C" to terminate the program.
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7.2 DE1-SoC Control Panel
The DE1-SoC Control Panel is a more comprehensive example. It demonstrates:
Control HPS LED and FPGA LED/HEX
Query the status of buttons connected to HPS and FPGA
Configure and query G-sensor connected to HPS
Control Video-in and VGA-out connected to FPGA
Control IR receiver connected to FPGA
This example not only controls the peripherals of HPS and FPGA, but also shows how to
implement a GUI program on Linux. Figure 7-4OLE_LINK4 is the screenshot of DE1-SOC
Control Panel.
Figure 7-4 Screenshot of DE1-SoC Control Panel
Please refer to DE1-SoC_Control_Panel.pdf, which is included in the DE1-SOC System CD for
more information on how to build a GUI program step by step.
7.3 DE1-SoC Linux Frame Buffer Project
The DE1-SoC Linux Frame Buffer Project is a example that a VGA monitor is utilized as a standard
output interface for the linux operate system. The Quartus II project is located at this path:
Demonstrations/SOC_FPGA/DE1_SOC_Linux_FB. The soc_system.rbf file in the project is used
for configuring FPGA through HPS. The .rbf file is converted form DE1_SOC_Linux_FB.sof by
clicking the sof_to_rbf.bat. The project is adopted for the following demonstrations.
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DE1_SoC Linux Console with framebuffer
DE1_SoC LXDE with Desktop
DE1_SoC Ubuntu Desktop
The SD image file for the demonstrations above can be downloaded in the design resources for
DE1-SoC at Terasic website.
These examples provide a GUI environment for further developing for the users. For example, a QT
application can run on the system.
Figure 7-5 Screenshot of DE1-SoC Linux Console with framebuffer
Please refer to DE1-SoC_Getting_Started_Guide about how to get the SD images and create a boot
SD card.
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Chapter 8
Programming the
EPCQ Device
This chapter describes how to program the quad serial configuration (EPCQ) device with Serial
Flash Loader (SFL) function via the JTAG interface. Users can program EPCQ devices with a
JTAG indirect configuration (.jic) file, which is converted from a user-specified SRAM object file
(.sof) in Quartus. The .sof file is generated after the project compilation is successful. The steps of
converting .sof to .jic in Quartus II are listed below.
8.1 Before Programming Begins
The FPGA should be set to AS x4 mode i.e. MSEL[4..0] = “10010” to use the quad Flash as a
FPGA configuration device.
8.2 Conver t .SOF File to .JIC File
1. Choose Convert Programming Files from the File menu of Quartus II, as shown in Figure
8-1.
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Figure 8-1 File menu of Quartus II
2. Select JTAG Indirect Configuration File (.jic) from the Programming file type field in
the dialog of Convert Programming Files.
3. Choose EPCQ256 from the Configuration device field.
4. Choose Active Serial x4 from the Model filed.
5. Browse to the target directory from the File name field and specify the name of output file.
6. Click on the SOF data in the section of Input files to convert, as shown in Figure 8-2.
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Figure 8-2 Dialog of “Convert Programming Files”
7. Click Add File.
8. Select the .sof to be converted to a .jic file from the Open File dialog.
9. Click Open.
10. Click on the Flash Loader and click Add Device, as shown in Figure 8-3.
11. Click OK and the Select Devices page will appear.
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Figure 8-3 Click on the “Flash Loader”
12. Select the targeted FPGA to be programed into the EPCQ, as shown in Figure 8-4.
13. Click OK and the Convert Programming Files page will appear, as shown in Figure 8-5.
14. Click Generate.
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Figure 8-4 “Select Devices” page
Figure 8-5 “Convert Programming Files” page after selecting the device
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8.3 Write JIC File into the EPCQ Device
When the conversion of SOF-to-JIC file is complete, please follow the steps below to program the
EPCQ device with the .jic file created in Quartus II Programmer.
1. Set MSEL[4..0] = “10010”
2. Choose Programmer from the Tools menu and the Chain.cdf window will appear.
3. Click Auto Detect and then select the correct device. Both FPGA device and HPS should be
detected, as shown in Figure 8-6.
4. Double click the green rectangle region shown in Figure 8-6 and the Select New
Programming File page will appear. Select the .jic file to be programmed.
5. Program the EPCQ device by clicking the corresponding Program/Configure box. A
factory default SFL image will be loaded, as shown in Figure 8-7.
6. Click Start to program the EPCQ device.
Figure 8-6 Two devices are detected in the Quartus II Programmer
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Figure 8-7 Quartus II programmer window with one .jic file
8.4 Erase the EPCQ Device
The steps to erase the existing file in the EPCQ device are:
1. Set MSEL[4..0] = “10010”
2. Choose Programmer from the Tools menu and the Chain.cdf window will appear.
3. Click Auto Detect, and then select correct device, both FPGA device and HPS will detected.
(See Figure 8-6)
4. Double click the green rectangle region shown in Figure 8-6, and the Select New
Programming File page will appear. Select the correct .jic file.
5. Erase the EPCQ device by clicking the corresponding Erase box. A factory default SFL
image will be loaded, as shown in Figure 8-8.
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Figure 8-8 Erase the EPCQ device in Quartus II Programmer
6. Click Start to erase the EPCQ device.
8.5 Nios II Boot from EPCQ Device in Quar tus II v13.1
There is a known problem in Quartus II software that the Quartus Programmer must be used to
program the EPCQ device on DE1-SoC board.
Please refer to Altera’s website here with details step by step.
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Chapter 9
Appendix
9.1
Revision Histor y
Version
V0.1
V0.2
V0.3
V0.4
V0.5
V1.0
V1.1
V1.2
Change Log
Initial Version (Preliminary)
Add Chapter 5 and Chapter 6
Modify Chapter 3
Add Chapter 3 HPS
Modify Chapter 3
Modify Chapter 8
Modify section 3.3
1. Add Sectiom 7.3
2. Modify Figure 3-2
Modify Figure 3-2
Modify Figure 5-5 descriptions of remote controller
V1.2.1
V1.2.2d
Copyright © 2015 Terasic Technologies. All rights reserved.
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