SmartFusion Evaluation Kit User’s Guide · 2018-09-04 · SmartFusion Evaluation Kit User’s Guide Revision 7 9 Never put a jumper on these headers. These are prov ided to measure

SmartFusion Evaluation KitUser’s Guide

SmartFusion Evaluation Kit User’s Guide

Table of Contents

Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5Kit Contents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5

Board Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6

1 Installation and Settings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7Software Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7

Jumpers, Switches, and LED Settings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7

2 Hardware Components . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11Description and Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11

I/O Pin Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13

SmartFusion Hard ARM Cortex-M3 Processor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14

Power Sources . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14

3 Component Descriptions and Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15VAREF Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15

Current Sensing Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16

PWM Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16

Push-Button System Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17

Push-Button Switches and User LEDs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17

User I/Os . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19

OLED Display . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19

SPI Flash . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20

20 MHz Oscillator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21

32.768 KHz (low power) Oscillator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21

USB-to-UART Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21

Ethernet Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24

RealView Header . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26

Integrated Low-Cost Programmer (LCP) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27

Temperature Diode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28

Mixed Signal Header . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29

Pinout Definition . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31

4 Pin List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33

5 Board Stackup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47Board Stack-Up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47

6 Demo Design . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49Jumper Settings for Demo Design . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49

Running the Demo Design . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49

Multimeter Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51

Webserver Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51

Real Time Data Display . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53

LED Test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53

Revision 7 2


7 Manufacturing Test. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55A2F-EVAL-KIT-2 Board Testing Procedures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55

Running the A2F-EVAL-KIT Board Test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64

A2F-EVAL-KIT Board Failures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80

A List of Changes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81

B Product Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83Customer Service . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83

Customer Technical Support Center . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83

Technical Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83

Website . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83

Contacting the Customer Technical Support Center . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83

ITAR Technical Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84

Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85

Revision 7 3

Introduction

The RoHS-compliant SmartFusion® Evaluation Kit (A2F-EVAL-KIT-2) enables designers to developapplications that involve one or more of the following:

• Microcontroller applications

• Embedded ARM® Cortex™-M3 processor–based systems

Kit ContentsTable 1 lists the contents of the SmartFusion Evaluation Kit.

Figure 1 • A2F-EVAL-KIT-2

10/100 EthernetInterface

Regulators

USB Program &Debug Interface

SmartFusion Device

User SW2

USB Power &USB-UART Interface

Potentiometer

Reset Switch

J22 – Debug I/Os

JP8 – UART Header

JP9 – I2C Header

JP11 – LEDJP12 – LEDJP13 – LEDJP14 – LED

JP7 – Debug Select

JP10 – JTAG Select

8 User LEDs

OLED DisplayRVI – Header

SPI-Flash Memory

J23 – SPI Header

PU_N Switch

JP 6 – VRPSM Voltage Option

20 MHzCrystal

32.768 KHzCrystal

J24 –VAREFOUT/

VAREF Header

User SW1 Mixed SignalHeader

Table 1 • A2F-EVAL-KIT-2 Contents

Quantity Description

1 SmartFusion Evaluation Board with SmartFusion A2F200M3F-FGG484 device

2 USB 2.0 A to mini-B cable

1 Quickstart card

Revision 7 5

Introduction

Board DescriptionThe SmartFusion Evaluation Kit board is designed to provide a development platform for users to evaluate all the features of the world’s only customizable system-on-chip with a hard ARM Cortex-M3 processor powered microcontroller subsystem (MSS) along with programmable analog.

The board supports a SmartFusion cSoC in an FG484 package to enable the MSS, analog, and features for evaluation.

The board includes the following:

• Ethernet and USB-to-UART interface for communication with the Ethernet and UART peripherals of the SmartFusion MSS

• SPI flash that interfaces with the SPI peripherals of the SmartFusion MSS

• Organic light-emitting diode (OLED) display that interfaces with the I2C peripheral of the SmartFusion MSS

• I2C Interface

• Current monitoring and temperature monitoring circuits

• RVI header for application programming and debug from either Keil® U-LINK® or IAR J-Link, integrated low-cost programmer to enable programming and debugging from Microsemi design tools, FlashPoint and Soft Console.

Table 2 describes the SmartFusion Evaluation Kit board components.

Table 2 • SmartFusion Evaluation Kit Board Components

Name Description

A2F200M3F-FGG484 Microsemi SmartFusion cSoC with hard ARM Cortex-M3 processor

OLED DISPLAY Organic 96×16 pixel white OLED PMO18701 with option to interface either with I2C0 port of SmartFusion MSS

SPI FLASH 8 MByte SPI flash Atmel AT25DF641-MWH-T connected to SPI port 0 of the SmartFusion MSS

OSC-20 20 MHz / 20 PPM clock oscillator

OSC-32 32.768 KHz low power oscillator

USB/UART USB-to-UART adapter chip CP2102 and connector interfacing with UART port 0 of the SmartFusion MSS

ETHERNET RJ45 connector (Ethernet jack with magnetics) interfacing with National Semiconductor 10/100 PHY chip DP83848C in RMII mode interfacing with Ethernet port of SmartFusion MSS (on-chip MAC and external PHY)

CURRENT Current monitoring using thumbwheel POT (RV1)

TEMP Temperature monitoring with temperature diode

RVI HEADER RVI header for application programming and debug from Keil U-LINK or IAR J-Link

FP3_PROG Integrated low-cost programmer

PUSH-BUTTON SWITCHES

Two push-button switches connected to GPIOs, which can be used as test and navigation switches

LEDS Eight active low LEDs that can be connected to user I/O for debug to power on the board

USER I/Os Five general purpose user I/Os that can be used for Direct-C signaling, interfacing and debugging purposes

PUSH-BUTTON RESET Push-button system reset for SmartFusion cSoC system

MIXED_CONN100 Mixed signal header

6 Revision 7

1 – Installation and Settings

Software InstallationDownload and install the latest release of Microsemi Libero® System-on-Chip (SoC) (v10.0 or later) fromthe Microsemi SoC Products Group website and register for your free Gold license. For instructions onhow to install Libero SoC and SoftConsole, refer to the Libero SoC Installation and Licensing Guide,available at www.microsemi.com/soc/documents/libero_ug.pdf.

Refer to the Installing IP Cores and Drivers User’s Guide for downloading and installing MicrosemiDirectCores, SGCores, and Driver firmware cores that must be localized on the personal computerwhere Libero SoC is installed when designing with Microsemi devices.

Microsemi has partnered with key industry leaders in the microcontroller space to provide a robustSmartFusion ecosystem. SmartFusion cSoCs are supported by the latest IAR Systems® release, IAREmbedded Workbench® for ARM. Refer to Designing SmartFusion with IAR Systems for moreinformation.

The SmartFusion cSoC is also supported by Keil’s latest release, MDK-ARM MicrocontrollerDevelopment Kit. Refer to SmartFusion Designing with Keil for more information.

Jumpers, Switches, and LED SettingsThe recommended default jumpers, switches, LEDs, and DIP switch settings are defined in Table 1-1through Table 1-4 on page 8. Connect the jumpers with the default settings to enable the pre-programmed demonstration design to function correctly.

The available headers and their usage are detailed in Table 1-5 and Table 1-6 on page 9.

Table 1-1 • SmartFusion Evaluation Kit Jumper Settings

Jumper Function Default Settings Notes

J6 Jumper to select second 3.3 V (V3P3_F2) power supply for board

Closed

JP6 Jumper to select either 1.5 V external regulator or SmartFusion 1.5 V internal regulator

Pin 1–2 = 1.5 V internal Closed

Pin 2–3 = 1.5 V external Open

JP7 Jumper to select between RVI header or LCP header for application debug

–

Pin 1–2 = USB programming and SoftConsole Closed

Pin 2–3 = RVI for Keil U-LINK/IAR J-ink Open

JP10 Jumper to select JTAGSEL Allows selection of A2F200 programming or Cortex-M3 processor debug with integrated low-cost programmer

Pin 1–2 = FPGA, allows A2F200 programming Closed

Pin 2–3 = M3, allows Cortex-M3 processor debug

Open

Revision 7 7

www.microsemi.com/soc/documents/libero_ug.pdf

http://www.microsemi.com/soc/documents/installing_ip_cores_drivers_ug.pdf

http://www.microsemi.com/soc/products/smartfusion/ecosystem.aspx



http://www.microsemi.com/soc/documents/SmartFusion_IAR_RS.pdf

http://www.microsemi.com/soc/documents/SmartFusion_IAR_RS.pdf

http://www.microsemi.com/soc/documents/SmartFusion_Keil_RS.pdf



Installation and Settings

Table 1-2 • SmartFusion Evaluation Kit Push-Button Switches

Push-Button Switch SmartFusion Pin Comments

SW1 G19 Test and navigation switch

SW2 G20 Test and navigation switch

SW3 W7 (PU_N) Push-button switch for PUB. This negative active switch is connected to the PUB pin, which is a digital input to the FPGA fabric. PUB is the connection for the external momentary switch used to turn on the 1. 5 V voltage regulator.

SW4 R1 (MSS_SYSRESET) System Reset for DUT

Table 1-3 • SmartFusion Evaluation Kit LED

LEDSmartFusion

Pin Comment

D1 B19 Test LED for user application

D2 B20 Test LED for user application

D3 C19 Test LED for user application

D4 H17 Test LED for user application

D5 H20 Test LED for user application

D6 C21 Test LED for user application

D7 D21 Test LED for user application

D8 G21 Test LED for user application

D11 N/A UART over USB link indicator LED

D14 N/A Programmer activity indicator LED

D15 N/A Programmer ON indicator LED

D16 N/A SPEED LED. The LED is ON when device is in 100 Mbps mode and OFF when in 10 Mbps mode.

LED1 N/A USB power supply indicator LED. This GREEN LED is ON when the board is powered on.

Table 1-4 • LED Table

Jumper LED Comment

JP11 D5 Controls LED access for LED5




Table 1-5 • Test Point

Pin FPGA I/O

TP7, TP8 Digital ground (GND)

TP11 3.3 V supply for SmartFusion cSoC

8 Revision 7


Never put a jumper on these headers. These are provided to measure and monitor VAREF0 and VAREF1.

TP12 1.5 V for SmartFusion cSoC

TP13 Analog ground (AGND)

Table 1-6 • J22 Header Strip – User I/Os

Pin FPGA I/O

1 J19

2 J20

3 J21

4 J22

Table 1-7 • Header for VAREF Monitoring

Jumper Description

J5 Used to monitor VAREF0 driven from VAREFOUT output of the SmartFusion device

J8 Used to monitor VAREF1 driven from VAREFOUT output of the SmartFusion device

J24 Header for VAREFOUT/VAREF output of the SmartFusion Device

Table 1-8 • JP8 UART Header

Pin MSSIO/GPIO

1 28 - UART_1_TXD1

2 29 - UART_1_RXD1

3 GND

Table 1-9 • JP9 I2C Header

Pin MSSIO/GPIO

1 30 - I2C_1_SDA1

2 31 - I2C_1_SCL1

3 GND

Table 1-10 • J23 SPI Header

Pin MSSIO/GPIO

1 24 - SPI_1_DO

2 25 - SPI_1_DI

3 26 - SPI_1_CLK

4 27 - SPI_1_SS

5 GND

Table 1-5 • Test Point (continued)

Pin FPGA I/O

Revision 7 9

2 – Hardware Components

Description and ConnectionsThe SmartFusion Evaluation Kit Board is populated with a SmartFusion A2F200-FG484. The keyfeatures of the SmartFusion cSoC are listed below.

The microcontroller subsystem (MSS) consists of the following:

• 100 MHz 32-bit ARM Cortex-M3 processor

– 1.25 DMIPS/MHz throughput from zero wait state memory

• Internal memories

– Embedded flash memory (eNVM), 64 Kbytes to 512 Kbytes

– Embedded high-speed SRAM (eSRAM), 16 Kbytes to 64 Kbytes, implemented in two physicalblocks to enable simultaneous access from two different masters

• Multi-layer AHB communications matrix

– Provides up to 16 Gbps of on-chip memory bandwidth

• 10/100 Ethernet MAC with RMII interface

• Programmable external memory controller, which supports the following:

– Asynchronous memories

– NOR flash, SRAM, PSRAM

– Synchronous SRAMs

• Two I2C peripherals

• Two 16550 compatible UARTs

• Two SPI peripherals

• Two 32-bit timers

• 32-bit watchdog timer

• 8-channel DMA controller

• Clock sources

– 1.5 MHz to 20 MHz main oscillator

– Battery-backed 32 KHz low power oscillator with real-time counter (RTC)

– 100 MHz embedded RC oscillator 1% accuracy

– Embedded PLL with 4 output phases

• High-performance FPGA

• Based on Microsemi's proven ProASIC®3 FPGA fabric

• Analog front-end (AFE)

• Up to three 12-bit SAR analog-to-digital converters (ADCs)

• One first-order (sigma delta) digital-to-analog converter (DAC) per ADC

• Up to 5 new high-performance analog signal conditioning blocks (SCB) per device

• Two high-speed comparators

• Analog compute engine (ACE)

– Offloads CPU from analog initialization and processing of ADC, DAC, and SCBs

– Sample sequencing engine for ADC and DAC parameter setup

– Post-processing engine (PPE) for functions such as low-pass filtering and lineartransformation

Revision 7 11

Hardware Components

Table 2-1 • A2F200 Key Features

Feature Specification

System gates 200,000

Tiles (D-flip flops) 4,608

RAM blocks (4,608 bits) 8

Flash (Kbytes) 256

SRAM (Kbytes) 64

Cortex-M3 processor with MPU 1

10/100 Ethernet MAC Yes

Ethernet memory controller (EMC) 26-bit address, 16-bit data

DMA 8 Ch

I2C 2

SPI 2

16550 UART 2

32-bit timer 2

PLL 1

32 KHz low power oscillator 1

100 MHz on-chip RC oscillator 1

Main oscillator 1

ADCs (12-bit SAR) 2

DACs (1-bit sigma-delta) 2

Signal conditioning blocks (SCBs) 4

Comparators* 8

Current monitor* 4

Temperature monitors* 4

HV bipolar voltage monitors* 8

Direct analog input to ADC* 18

Note: *The maximum available resources have dependencies. For additional information on SmartFusion cSoCs, refer to the SmartFusion Customizable System-on-Chip (cSoC) datasheet.

12 Revision 7

http://www.microsemi.com/soc/documents/SmartFusion_DS.pdf

http://www.microsemi.com/soc/documents/SmartFusion_DS.pdf


I/O Pin ConnectionsThe A2F200M3F-FGG484 pin list is provided in the "Pin List" section on page 33.

Table 2-2 • A2F200 I/O

I/Os FG484

Direct analog input 8

Total analog input 24

Total analog output 2

MSS I/O 42

FPGA I/O 94

Total I/O 161

Notes:

1. 16 MSS I/Os are multiplexed and can be used as FPGA I/Os, if not needed for the MSS. These I/Os support Schmitt triggers and support only LVTTL and LVCMOS (1.5 / 1.8 / 2.5, and 3.3 V) standards.

2. 9 MSS I/Os are primarily for 10/100 Ethernet MAC and are also multiplexed and can be used as FPGA I/Os if Ethernet MAC is not used in a design. These I/Os support Schmitt triggers and support only LVTTL and LVCMOS (1.5 / 1.8 / 2.5, and 3.3 V standards.

Figure 2-1 • SmartFusion MSS Block Diagram

Revision 7 13

Hardware Components

SmartFusion Hard ARM Cortex-M3 ProcessorThe SmartFusion cSoC comes with a hard Cortex-M3 advanced processor-based MSS. The ARMCortex-M3 microcontroller is a low power processor that features low gate count, low predictableinterrupt latency, and low cost debug. It is intended for deeply embedded applications that require fastinterrupt response features. SmartFusion cSoCs use the R1P1 version of the Cortex-M3 processor core.Some of the important subsystems are listed below:

• Memory protection unit (MPU)

• Single cycle multiplication and hardware divide

• JTAG debug (4 wire), Serial Wire Debug (SWD – 2 wire), and Serial Wire Viewer (SWV)interfaces

The Evaluation board is populated with components to enable development using the MSS. Thesecomponents include SPI flash, OLED, and communication interfaces such as Ethernet and USB-to-UART.

Power Sources

SmartFusion Power SourcesThe Evaluation Kit board is powered through USB. The USB power will supply power to three voltagerails: 3.3 V, 1.5 V, and 10 V.

• Microsemi NX4108 (1 A), supplies 3.3 V and 1.5 V rails

• Linear LT1615 step-up converter supplies 10 V, 100 mA typical, for driving the OLED

The USB can provide a maximum current of 500 mA. If the application requires a daughter board, you must use an independent power supply source.

14 Revision 7

3 – Component Descriptions and Connections

VAREF ConnectionsThe SmartFusion cSoC has one external VAREF input pin for each of the ADCs in the device. These areVAREF0 for ADC0 and VAREF1 for ADC1 (Figure 3-1). The internal VAREF is brought out as an output.This is available as the VAREFOUT header J24.

On the A2F-EVAL-KIT-2 board, the VAREF0 and VAREF1 inputs are hardwired to the VAREFOUT outputof the SmartFusion cSoC (Figure 3-2). This means you should not drive these inputs from any externalsource. Three headers J5, J8, and J24 are provided to monitor the VAREF0, VAREF1 and VAREFOUTfor any debug purposes.

Figure 3-1 • VAREFOUT to VAREF0 and VAREF1

Figure 3-2 • VAREF0 and VAREF1 Inputs of FPGA

VAREF_OUT

ADC0

DACOUT0

DACOUT0

VAREF_OUT

ADC3

ADC4ADC5

DACOUT0

ADC2

AGND

AGND

AGND

AGND

AGND

AGND

VAREF0

VAREF1

12

J5

HEADER 1x2

J5

HEADER 1x2

12

J8

HEADER 1x2

J8

HEADER 1x2

C61 10uF-0805C61 10uF-0805

C63

10uF-0805

C63

10uF-0805

GN

DV

AR

EF

U15

VA

RE

FO

UT

T15

ADC2V9

ADC3AB8

ADC4U12

ADC5V12

ADC0Y9

ADC1AA8

SDD0V7

A2F200M3F-FGG484A2F200M3F-FGG484C234 NL-0.1uF-0402C234 NL-0.1uF-0402

C62

10uF-0805

C62

10uF-0805

R501 1K,1%-0603R501 1K,1%-0603

C244 0.1uF-0402C244 0.1uF-0402

VAREF0VAREF1

VAREF_OUTJ24

HEADER 2X2

34

12

VAREF_OUT VAREF_OUT

AT0AT2

VAREF0 VAREF1

R194 1K,1%-0603R194 1K,1%-0603

C204 0.1uF-0402C204 0.1uF-0402 C208 0.1uF-0402C208 0.1uF-0402

TM0W8

VAREF1 AB11VAREF0U10

TM2 AB12

QQ

R131 1K,1%-0603R131 1K,1%-0603

Revision 7 15

Component Descriptions and Connections

Current Sensing CircuitA current sensing circuit is provided on the SmartFusion Evaluation Kit board for applications using theembedded current monitor. Current monitoring is performed across the AC0 and AT0 pins. The currentsensing circuit is for the 3.3 V voltage rail, as shown in Figure 3-3.

PWM CircuitThe PWM RC circuit depicted in Figure 3-4 and Figure 3-5 can be used with Microsemi CorePWMinstantiated in the FPGA fabric to generate various voltage waveforms. These voltage waveforms can bedisplayed on the OLED or used via the mixed signal header. In addition, one PWM RC circuit source isrouted to the AV input pin of an analog quad. This AV pin can be used to monitor the generated voltagewith high accuracy, depending on the ADC resolution configured in the FPGA.

Figure 3-5 shows A2F200 pins driving PWM and the PWM circuit.

Figure 3-3 • Current Sensing

AT0 AC0 V3P3

R6 100R,1%-0805R6 100R,1%-0805R7 5K36-0805R7 5K36-080513

2

50K_POT3352P-1-503LF

50K_POT3352P-1-503LF

D17DL4007-MelfD17DL4007-Melf

Figure 3-4 • PWM Pins

Figure 3-5 • PWM Circuit

F2-200-IO_0

DACOUT1

F2-200-IO_1 F2-200-IO_2

DACOUT0

PWM0F2-200-IO_8

PWM1

F2-200-IO_3F2-200-IO_5

MSS_GP_IO_14 MSS_GP_IO_15

F2-200-IO_6F2-200-IO_7

F2-200-IO_4

F2-200-14-MSSIO25

F2-200-0-FPGAIO27

F2-200-1-FPGAIO29

DGND631

F2-200-4-FPGAIO33

F2-200-6-FPGAIO35

F2-200-7-FPGAIO37

F2-200 PWM039

DGND841

AGND143

OBD045

AGND347

F2-200-15-MSSIO 26

DGND5 28

F2-200-2-FPGAIO 30

F2-200-3-FPGAIO 32

F2-200-5-FPGAIO 34

DGND7 36

F2-200-8-FPGAIO 38

F2-200 PWM1 40

DGND9 42

AGND2 44

OBD1 46

AGND4 48

F2-200-PWM1

F2-200-PWM0PWM0

PWM1R316

4K7-00603R316

4K7-00603

R3144K7-00603

R3144K7-00603

R281 100K-0603R281 100K-0603

C283 220nF-0603C283 220nF-0603

C284 220nF-0603C284 220nF-0603

R289 100K-0603R289 100K-0603

16 Revision 7


Push-Button System ResetA push-button system reset switch with a Schmitt trigger is provided on the board (Figure 3-6). TheSchmitt trigger reduces noise on the system reset push-button. The SmartFusion MSS reset issynchronized with this reset.

Push-Button Switches and User LEDsPush-button switches and user LEDs (Figure 3-7) can also be used for debug and for variousapplications, such as gaming.

Figure 3-6 • Push-Button System Reset

V3P3V3P3

MSS_RESET_N

RST

C245

NL-0.1uF-0402

C245

NL-0.1uF-0402C74

NL-0603

C74

NL-0603

R34

10K-0603

R34

10K-0603

12

34

SW3

KSC403J 50SH LFG

SW3

KSC403J 50SH LFG

VCC2

GND3

RST 1

U53

NL-DS1818

U53

NL-DS1818

R35

39R-0603

R35

39R-0603

Figure 3-7 • Test LEDs

V3P3

LED3_N

LED2_N

LED1_N

LED4_N

LED7_N

LED6_N

LED5_N

LED8_N

ACTIVE LOWMfr P/N :SML-512DWT86Mfr: Rohm

ACTIVE LOW

D6

LED_ORANGE-0603

D6

LED_ORANGE-0603

D8

LED_ORANGE-0603

D8

LED_ORANGE-0603

R55 1.5K-0603R55 1.5K-0603

R54 1.5K-0603R54 1.5K-0603

R39 1.5K-0603R39 1.5K-0603

R33 1.5K-0603R33 1.5K-0603

R77 1.5K-0603R77 1.5K-0603

D2

LED_ORANGE-0603

D2

LED_ORANGE-0603

R36 1.5K-0603R36 1.5K-0603

D3

LED_ORANGE-0603

D3

LED_ORANGE-0603

D7

LED_ORANGE-0603

D7

LED_ORANGE-0603

D4

LED_ORANGE-0603

D4

LED_ORANGE-0603D5

LED_ORANGE-0603

D5

LED_ORANGE-0603

D1

LED_ORANGE-0603

D1

LED_ORANGE-0603

R79 1.5K-0603R79 1.5K-0603

R40 1.5K-0603R40 1.5K-0603

Revision 7 17


The board provides users access to eight active low LEDs (Figure 3-9), which are connected toSmartFusion cSoC pins B19, B20, C19, H17, H20, C21, D21, and G21.

Jumpers JP11, JP12, JP13 and JP14 grant users control options over four of the LEDs. In addition, theboard includes two push-button switches (Figure 3-10 on page 18) that are connected to pins G19 andG20 of the SmartFusion cSoC.

Figure 3-8 • LEDs

Figure 3-9 • 3-Pin Jumper Options for LED

Figure 3-10 • Push-Button Switches

LED1_N

LED2_N

LED3_N

LED4_N

SWITCH1

SWITCH2

LED5_N

LED6_N

LED7_N

LED8_N

GBB0/IO18NDB0V0B19

GBB1/IO18PDB0V0B20

GBA0/IO19NPB0V0C19

GBC2/IO21PDB1V0C21

IO21NDB1V0D21

IO23NDB1V0 F19

GCA2/IO23PDB1V0 G19

IO24NDB1V0 G20

GCB2/IO24PDB1V0 G21IO25NDB1V0H17

GCC0/IO26NPB1V0H20

GFC2/IO67PPB5V0 E1

GBC0/IO17NPB0V0 E14

LED , DIP & PB

U64-17

A2F200M3F-FGG484

LED , DIP & PB

U64-17

A2F200M3F-FGG484

LED8_NLED7_N

LED6_NLED5_N

LED5_N_H20

LED7_N_D21

LED6_N_C21

LED8_N_G21

MSSIO28 - TXD1_V20 MSSIO29 - RXD1_W22

MSSIO30 - SDA1_V22 MSSIO31-SCL1_U20

JP14

1

2

3

JP12

1

2

3

JP11

1

2

3

JP13

1

2

3

V3P3 V3P3

SWITCH1 SWITCH2

Mfr P/N :KSC403J 50SH LFGPanasonic - C&K Components

Mfr P/N :KSC403J 50SH LFGPanasonic - C&K Components

1 2

3 4

SW1

KSC403J 50SH LFG

SW1

KSC403J 50SH LFG

1 2

3 4

SW2

KSC403J 50SH LFG

SW2

KSC403J 50SH LFG

R43

10K-0603

R43

10K-0603

R44

10K-0603

R44

10K-0603

18 Revision 7


User I/OsThe board comes with the provision of five user I/Os brought out to jumper J22 (Figure 3-11). These canbe used as general purpose user I/Os. One of the potential applications is DirectC signaling where thesefive pins can be used for JTAG signals (TDI, TDO, TMS, TCK, and TRSTN). Other possible uses are forinterfacing with other boards and debugging.

OLED DisplayA 96x16-pixel matrix low power OLED is made available on the board for display (Figure 3-12 onpage 19). This low power device, WHITE OLED, requires 3.3 V and 10 V power supplies. The OLED isinterfaced with the SmartFusion MSS I2C0 port (Figure 3-13 on page 20). The OLED displays sharpgaming images or text.

For example, the SmartFusion RTC current time or time between two events can be displayed on theOLED. The OLED inputs OLED_BS1, OLED_BS2, and OLED_CSN are tied off and OLED_D/C# ispulled down as required to work with I2C mode.

Figure 3-11 • User I/Os

J19

J20

J21

J22

K19

12345

J22

5x1 Header(M)

J22

5x1 Header(M)

Figure 3-12 • OLED Connections

OLED_BS1

OLED_CS#

OLED_BS2

V3P3V10PV3P3

V3P3

MSS_RESET_N

OLED_SCL

OLED_SDA

OLED_D/C#

Mfr P/N :PMO13701Mfr: PACER

TANT

SCL

SDA

R210

1K-0603

R210

1K-0603

R165

1K-0603

R165

1K-0603

R18

10K-0603

R18

10K-0603

C69

1uF-0603

C69

1uF-0603

R207

10K-0603

R207

10K-0603

VC

C30

VCOMH 29IREF28

VD

D11

BS112 BS2 13

NC

11

NC

28

NC

39

NC

410

NC

514

NC

631

VS

S2

TEST17

TEST26

TEST35

TEST44

TEST53

D0 20

D1 21

D2 22

D3 23

D4 24

D5 25

D6 26

D7 27

RD# 19

WR# 18D/C#17

RES#16

CS#15

NC

732

NC

833

U11

PMO13701

U11

PMO13701

R17

10K-0603

R17

10K-0603

C68

0.01uF-0603

C68

0.01uF-0603

R201

10K-0603

R201

10K-0603

+C67

4.7uF 25V-TantA

+C67

4.7uF 25V-TantA

R20

2M-0603

R20

2M-0603

Revision 7 19


SPI FlashOne 8 MByte SPI flash Atmel AT25DF641-MWH-T is also offered on the board (Figure 3-14). This isinterfaced with the SmartFusion MSS SPI0 port (Figure 3-15). The WP# and HOLD# inputs are pulledhigh on the board.

Figure 3-13 • SmartFusion MSS I2C0 Interface

OLED_SDA

OLED_SCL I2C_0_SCL/GPIO_23U21

I2C_0_SDA/GPIO_22V21

I2C_1_SDA/GPIO_30V22

I2C_1_SCL/GPIO_31U20

I2C INTERFACEPORT0

PORT1

U64-16

A2F200M3F-FGG484

I2C INTERFACEPORT0

PORT1

U64-16

A2F200M3F-FGG484

Figure 3-14 • SPI Flash

Figure 3-15 • SmartFusion MSS SPIO Port

SPI_CS_N

SPI_SCKSPI_SI

SPI_WP_NSPI_SO

V3P3

V3P3

8 MByte

Mfr P/N : AT25DF641-MWH-TMfr: Atmel

R209

10K-0603

R209

10K-0603

R208

10K-0603

R208

10K-0603

R206 39R-0603R206 39R-0603

C70

0.1uF 10V-0402

C70

0.1uF 10V-0402

SI5

SCK6

HOLD7

CS1

WP3

VCC 8

GND 4SO2E_GND 9

U13

AT25DF641-MWH-T

U13

AT25DF641-MWH-T

SPI_CS_N

SPI_SI

SPI_SO

SPI_SCK

SPI_0_DO/GPIO_16U17

SPI_0_SS/GPIO_19Y20

SPI_0_DI/GPIO_17V18

SPI_0_CLK/GPIO_18W19

SPI_1_DO/GPIO_24 T17

SPI_1_DI/GPIO_25 V19

SPI_1_CLK/GPIO_26 AA22

SPI_1_SS/GPIO_27 W21

SPI INTERFACE

PORT0 PORT1

U64-15

A2F200M3F-FGG484

SPI INTERFACE

PORT0 PORT1

U64-15

A2F200M3F-FGG484

R235 39R-0603R235 39R-0603

20 Revision 7


20 MHz OscillatorA 20 MHz resonator of 20 PPM is placed across the MAINXIN and MAINXOUT pins of the SmartFusioncSoC with the appropriate 18 pF capacitors (Figure 3-16). This is used to generate a high precision clockfor Ethernet MAC and is also used in real-time counter (RTC) based applications.

32.768 KHz (low power) OscillatorA 32.768 KHz Resonator CM519 is placed across the LPXIN and LPXOUT pins of the SmartFusioncSoC with the appropriate 30 PF capacitors (Figure 3-16). This low power resonator is useful in real-timecounter (RTC) based applications.

USB-to-UART InterfaceIncluded on the evaluation board is a USB-to-UART interface with ESD protection (Figure 3-17 onpage 23). This interface includes an integrated USB-to-UART bridge controller (U16) to provide astandard UART connection with the SmartFusion MSS UART0 port. One application of the USB-to-UART interface is to allow HyperTerminal on a PC to communicate with the SmartFusion cSoC.HyperTerminal is a serial communications application program that can be installed in the Windows®

operating system. A basic HyperTerminal program is usually distributed with Windows. With a USB driverproperly installed, and the correct COM port and communication settings selected, you can use theHyperTerminal program to communicate with a design running on the SmartFusion cSoC.

Figure 3-16 • 20 MHz and 32.768 MHz Oscillators

PTBASE

V1P5_INTV1P5_INTV1P5_INT

RTC_SW

RESET CIRCUIT

AGND AGND

AGND AGND

PCAP AB5

NCAP AB6

PU_N W17

PTBASE AB20

PTEM Y18

MAINXINAA16

LPXINAA18

MAINXOUTAA17

LPXOUTAA19

U64-2

A2F200M3F-FGG484

U64-2

A2F200M3F-FGG484

Y2

CM519 32.768KDZF-UT

Y2

CM519 32.768KDZF-UT

C52

30pF-0603

C52

30pF-0603

Y1

ABM3-20.000MHZ-B2-T

Y1

ABM3-20.000MHZ-B2-T

C53

0.1uF-0402

C53

0.1uF-0402

C48

18pF-0603

C48

18pF-0603

C51

30pF-0603

C51

30pF-0603

C50

18pF-0603

C50

18pF-0603

12

34

SW4

KSC403J 50SH LFG

SW4

KSC403J 50SH LFG

12

C49

2.2uF 16V-0603

C49

2.2uF 16V-0603

Revision 7 21


Table 3-1 lists the supported UART parameters for HyperTerminal applications.

Table 3-1 • UART HyperTerminal Settings

Supported HyperTerminal Parameters

Baud Rates Data Bits Parity Types STOP BIT

110 5, 6, 7, 8 NO/ODD/EVEN/MARK(1)/SPACE(0) ONE/ONE-HALF/TWO

300

1200

2400

4800

9600

19200

38400

57600

115200

230400

460800

921600

22 Revision 7


Figure 3-17 shows the USB-to-UART connections and Figure 3-18 on page 24 shows the UART0 port.

Figure 3-17 • USB to UART

D1

-

D1

+

D-

D+

VD

D

VD

D

VU

SB

RX

D_

0_

INT

XD

_0

_O

UT

Mfr P/N :BLM31PG500SN1L

Mfr: Murata

C7

8

0.1

uF

-04

02

C7

8

0.1

uF

-04

02

R5

23

9R

-06

03

R5

23

9R

-06

03

R4

9

0R

-06

03

R4

9

0R

-06

03

FB

3B

LM

31

PG

50

0S

N1

L-1

20

6F

B3

BL

M3

1P

G5

00

SN

1L

-12

06

VB

US

8

RE

GIN

7

VD

D6

NC

11

0

NC

21

3

NC

31

4

NC

41

5

NC

51

6

NC

61

7

D-

5

D+

4

GND3

GNDNW30

GNDCNTR29

RS

T9

NS

US

PE

ND

11

SU

SP

EN

D1

2

NC

71

8

NC

81

9

NC

92

0

NC

10

21

NC

11

22

DT

R2

8

RT

S2

4

CT

S2

3

DS

R2

7

RI

2

TX

D2

6

RX

D2

5

DC

D1

U1

6

CP

21

02

-GM

MA

NU

FA

CT

UR

ER

P/N

= C

P2

10

2-G

MM

AN

UF

AC

TU

RE

R =

Sili

co

n L

ab

ora

torie

s In

c

U1

6

CP

21

02

-GM

MA

NU

FA

CT

UR

ER

P/N

= C

P2

10

2-G

MM

AN

UF

AC

TU

RE

R =

Sili

co

n L

ab

ora

torie

s In

c

R5

1

10

K-0

60

3

R5

1

10

K-0

60

3C

76

1u

F-0

60

3

C7

6

1u

F-0

60

3

R5

0

14

7R

-06

03

R5

0

14

7R

-06

03

11

TP

V1-D

TR

TP

_V

IA

TP

V1-D

TR

TP

_V

IA

11

TP

V2-D

SR

TP

_V

IA

TP

V2-D

SR

TP

_V

IA

11

TP

V4

-DC

D

TP

_V

IA

TP

V4

-DC

D

TP

_V

IA

D1

1

LE

D_

GR

EE

N-0

60

3

D1

1

LE

D_

GR

EE

N-0

60

3

F2

MIC

RO

SM

D0

50

F-2

-12

10

MA

NU

FA

CT

UR

ER

P/N

= M

ICR

OS

MD

050F

-2M

AN

UF

AC

TU

RE

R =

Tyco

F2

MIC

RO

SM

D0

50

F-2

-12

10

MA

NU

FA

CT

UR

ER

P/N

= M

ICR

OS

MD

050F

-2M

AN

UF

AC

TU

RE

R =

Tyco

R4

91

0R

-06

03

R4

91

0R

-06

03

11

TP

V3-R

I

TP

_V

IA

TP

V3-R

I

TP

_V

IA

C7

7

0.1

uF

-04

02

C7

7

0.1

uF

-04

02

VB

US

1

D-

2

D+

3

NC

4

GN

D5

GN

D1

6

GN

D2

7

GN

D3

8

GN

D4

9

NC

_1

10

NC

_2

11

J1

4

US

B_

MIN

I_R

EC

EP

J1

4

US

B_

MIN

I_R

EC

EP

R5

30

R-0

60

3R

53

0R

-06

03

IO1

A1

G2

IO2

A3

IO2

B4

V5

IO1

B6

U1

7

US

BL

C6

-2S

C6

MA

NU

FA

CT

UR

ER

P/N

= U

SB

LC

6-2

SC

6M

AN

UF

AC

TU

RE

R =

ST

Mic

ro.

U1

7

US

BL

C6

-2S

C6

MA

NU

FA

CT

UR

ER

P/N

= U

SB

LC

6-2

SC

6M

AN

UF

AC

TU

RE

R =

ST

Mic

ro.

Revision 7 23


Ethernet InterfaceOne Ethernet interface, configured for RMII Full Duplex mode, and a low power 10/100 Mbps single-portEthernet physical layer transceiver (U19) are provided on-board (Figure 3-20 on page 25). The Ethernetphysical layer features integrated sub-layers to support both 10BASE-T and 100BASE-TX Ethernetprotocols. These sub-layers ensure compatibility and interoperability with many other standards-basedEthernet solutions.

The Ethernet RJ45 interface and physical layer interface with the SmartFusion MSS Ethernet mediaaccess controller (MAC), which supports RMII, serve many purposes. For example, these interfaces canbe used to access the SmartFusion cSoC to monitor the ADC data over a network. The embeddedsystem memory and control registers can be accessed and processed remotely to support systemmanagement.

Clocking Scheme for RMII CLKThe 10/100 MAC RMII interface requires a 50 MHz clock. The PHY device also requires a 50 MHz20 PPM clock for proper operation. While there are several possible ways of providing the clock, thefollowing clocking scheme has been tested on the board.

• The 20 MHz oscillator feeds the CCC input. The CCC, GLC output is configured as 50 MHz

• The GLC feeds the MAC_CLK (pin T6) input of the 10/100 MAC peripheral of the SmartFusionMSS

• The same GLC is routed through the fabric and feeds the X1 input of the Ethernet PHY device onthe board

Figure 3-18 • UART Port 0

RXD_0_IN

TXD_0_OUT UART_0_TXD/GPIO_20Y22

UART_0_RXD/GPIO_21U18

UART INTERFACE

PORT0

U64-9

A2F200M3F-FGG484

UART INTERFACE

PORT0

U64-9

A2F200M3F-FGG484

R236 39R-0603R236 39R-0603

Figure 3-19 • Ethernet Clocking Scheme

A2F200

CCC

20 MHzOscillator

10/100 MAC

MAC_CLKGLC

EthernetPHY

X1 Input

50 MHz Clock Output

TXD

RXD

50 MHz

24 Revision 7


Figure 3-20 • Ethernet Interface

LE

D_

AC

T

TD

-T

D+

LE

D_

AC

T

RD

+R

D-

V3P

3

V3P

3

V3

P3

V3

P3

V3

P3

V3P

3

V3P

3V

3P

3_E

TH

V3P

3_E

TH

V3P

3_E

TH

V3P

3_E

TH

PF

B

V3P

3

V3P

3

V3P

3

MS

S_R

ES

ET

_N

FP

GA

_E

NA

_C

RS

FP

GA

_E

NA

_M

DC

FP

GA

_E

NA

_M

DIO F

PG

A_E

NA

_T

XE

N

FP

GA

_E

NA

_R

XE

R

FP

GA

_E

NA

_T

XD

0F

PG

A_E

NA

_T

XD

1

FP

GA

_E

NA

_R

XD

1F

PG

A_

EN

A_

RX

D0

FP

GA

_E

NA

_M

DC

FP

GA

_E

NA

_M

DIO

FP

GA

_E

NA

_T

XE

NF

PG

A_

EN

A_

RX

D0

FP

GA

_E

NA

_R

XD

1

RM

II_

50

MH

Z_

CL

K

FP

GA

_E

NA

_C

RS

FP

GA

_E

NA

_T

XD

0

FP

GA

_E

NA

_T

XD

1

FP

GA

_E

NA

_R

XE

R

DECO

UPLI

NG C

APAC

ITOR

S

Mfr P/N :DP83848CVV/NOPB

Mfr: National Semiconductor

Mfr P/N :J0011D21B

Mfr: Pulse Tech

Mfr P/N :BLM31PG500SN1L

Mfr: Murata

Layout Note: Place 10uF capacitor

close to PFBOUT. PFBIN1 and

PFBIN2 pins should have a 0.1uF

capactiors placed right next to

the pins.

TANT

Mfr P/N :SML-512DWT86

Mfr: Rohm

R5

92

2R

-06

03

R5

92

2R

-06

03

C9

4

0.1

uF

10

V-0

40

2

C9

4

0.1

uF

10

V-0

40

2

R6

5

1.5

K-0

60

3

R6

5

1.5

K-0

60

3

C8

7

0.1

uF

10

V-0

40

2

C8

7

0.1

uF

10

V-0

40

2

MA

C_

MD

C/I

O4

8R

SB

4V

0A

A3

MA

C_

MD

IO/I

O4

9R

SB

4V

0V

4

MA

C_

TX

EN

/IO

52

RS

B4

V0

Y4

MA

C_

CR

SD

V/I

O5

1R

SB

4V

0W

4

MA

C_

RX

ER

/IO

50

RS

B4

V0

AA

4

MA

C_

TX

D[0

]/IO

56

RS

B4

V0

AA

5

MA

C_

TX

D[1

]/IO

55

RS

B4

V0

W5

MA

C_

RX

D[0

]/IO

54

RS

B4

V0

V5

MA

C_

RX

D[1

]/IO

53

RS

B4

V0

U5

MA

C_

CL

KT

6

ETHERNET

U6

4-1

4

A2F

200M

3F

-FG

G484

ETHERNET

U6

4-1

4

A2F

200M

3F

-FG

G484

C8

8 0.1uF 10V-0402

C8

8 0.1uF 10V-0402

R7

0

11

0R

-06

03

R7

0

11

0R

-06

03

R2

34

22

R-0

60

3R

23

42

2R

-06

03

R5

8

1.5

K-0

60

3

R5

8

1.5

K-0

60

3

D1

6

LE

D_

OR

AN

GE

-06

03

D1

6

LE

D_

OR

AN

GE

-06

03

+C9

0

10uF

16V

,TantA

+C9

0

10uF

16V

,TantA

R7

3N

l-4

.87

K-0

60

3R

73

Nl-4

.87

K-0

60

3

R7

44

.87

K-0

60

3R

74

4.8

7K

-06

03

R7

2

11

0R

-06

03

R7

2

11

0R

-06

03

R2

42

22

R-0

60

3R

24

22

2R

-06

03

R6

7 2.2K-0603

R6

7 2.2K-0603

C9

1

0.1

uF

10

V-0

40

2

C9

1

0.1

uF

10

V-0

40

2

C9

2

0.1

uF

10

V-0

40

2

C9

2

0.1

uF

10

V-0

40

2R6

32

2R

-06

03

R6

32

2R

-06

03

MD

IO3

0

MD

C3

1

CR

S/C

RS

_D

V/L

ED

_C

FG

40

CO

L/P

HY

AD

04

2

TX

_C

LK

1

TX

D_

03

TX

D_

14

TX

D_

25

TX

D_

3/S

NI_

MO

DE

6

TX

_E

N2

RX

_C

LK

38

RX

D_

0/P

HY

AD

14

3

RX

D_

1/P

HY

AD

24

4

RX

D_

2/P

HY

AD

34

5

RX

D_

3/P

HY

AD

44

6

RX

_E

R/M

DIX

_E

N4

1

RX

_D

V/M

II_

MO

DE

39

PW

R_

DO

WN

/IN

T7

PF

BIN

11

8

PF

BIN

23

7

PF

BO

UT

23

CL

K_

OU

T2

5

RE

SE

T_

N2

9

X2

33

X1

34

RB

IAS

24

TD

+1

7

TD

-1

6

RD

+1

4

RD

-1

3

LE

D_

AC

T/C

OL

/AN

_E

N2

6

LE

D_

SP

EE

D/A

N1

27

LE

D_

LIN

K/A

N0

28

RE

SE

RV

ED

18

RE

SE

RV

ED

29

RE

SE

RV

ED

31

0

RE

SE

RV

ED

41

1

RE

SE

RV

ED

51

2

RE

SE

RV

ED

62

0

RE

SE

RV

ED

72

1

AG

ND

11

5

AG

ND

21

9

DG

ND

36

IOG

ND

13

5

IOG

ND

24

7

AVDD3322

IOVDD33_132

IOVDD33_248

U1

9

DP

83

84

8C

VV

/NO

PB

U1

9

DP

83

84

8C

VV

/NO

PB

R6

0

49

.9R

-06

03

R6

0

49

.9R

-06

03

C9

5

0.1

uF

10

V-0

40

2

C9

5

0.1

uF

10

V-0

40

2

R6

2

1.5

K-0

60

3

R6

2

1.5

K-0

60

3

C8

4

0.1

uF

10

V-0

40

2

C8

4

0.1

uF

10

V-0

40

2

FB

5

BL

M3

1P

G5

00

SN

1L

-12

06

FB

5

BL

M3

1P

G5

00

SN

1L

-12

06

R6

9

2.2

K-0

60

3

R6

9

2.2

K-0

60

3

R5

6

49

.9R

-06

03

R5

6

49

.9R

-06

03

R6

42

2R

-06

03

R6

42

2R

-06

03

1 2 3 4 5 6 7 8

91

0

11

12

13

14

15

16

CHS

CHS

J1

0

J0

01

1D

21

B

CHS

CHS

J1

0

J0

01

1D

21

B

R6

1

49

.9R

-06

03

R6

1

49

.9R

-06

03

C9

6

0.1

uF

10

V-0

40

2

C9

6

0.1

uF

10

V-0

40

2

12

C8

9

10

00

pF

10

00

V-1

20

6

C8

9

10

00

pF

10

00

V-1

20

6

R7

1

2.2

K-0

60

3

R7

1

2.2

K-0

60

3

C9

3

0.1

uF

10

V-0

40

2

C9

3

0.1

uF

10

V-0

40

2

R6

8

11

0R

-06

03

R6

8

11

0R

-06

03

C9

7

10

uF

10

V,0

80

5

C9

7

10

uF

10

V,0

80

5

C8

6

0.1

uF

10

V-0

40

2

C8

6

0.1

uF

10

V-0

40

2

C8

5

0.1

uF

10

V-0

40

2

C8

5

0.1

uF

10

V-0

40

2

R2

33

22

R-0

60

3R

23

32

2R

-06

03

R5

7

49

.9R

-06

03

R5

7

49

.9R

-06

03

R6

62

2R

-06

03

R6

62

2R

-06

03

Revision 7 25


RealView HeaderOne 10x2 RealView® Header is provided on the board for debugging (Figure 3-21). This header allowsplugging with the Keil U-LINK debugger or IAR J-Link debugger to easily debug or configure the hardARM Cortex-M3 processor during board power-up.

The jumper settings shown in Table 3-2 are needed for debug with Keil U-LINK or IAR J-Link.

Figure 3-21 • RealView Header

Table 3-2 • RVI Header Jumper Settings

To Debug with Keil U-link or IAR J-link

Jumper Pin Pin Connection Details

JP7 2 3 To select RealView® JTG header

JP10 2 3 To select Cortex-M3 processor debug

RVI_nTRST

RVI_TDO

RVI_TMSRVI_TCK

RVI_TDI

V3P3

MSS_RESET_N

R12

10K-0603

R12

10K-0603

11

33

55

77

99

1111

1313

1515

1717

1919

2 2

4 4

6 6

8 8

10 10

12 12

14 14

16 16

18 18

20 20

J3

HEADER 10X2

MANUFACTURER P/N = HTST-110-01-L-DVMANUFACTURER = Samtec

J3

HEADER 10X2

MANUFACTURER P/N = HTST-110-01-L-DVMANUFACTURER = Samtec

R10

10K-0603

R10

10K-0603

R11

10

K-0

60

3

R11

10

K-0

60

3

26 Revision 7


Integrated Low-Cost Programmer (LCP)The board comes with a built-in programmer to program the SmartFusion cSoC device and debugsoftware with SoftConsole.

Figure 3-22 • integrated Low Cost Programmer

Table 3-3 • Jumper Settings to Debug with SoftConsole

To Debug with SoftConsole


JP7 1 2 To select the integrated low-cost programmer (LCP)

JP10 2 3 To select the Cortex-M3 processor debug.

LC

PS

_F

TD

I

CP

24

TR

ST

EN

B_N

VP

UM

PE

NB

LC

PS

_F

TM

SLC

PS

_F

TC

kLC

PS

_F

TR

ST

_N

CP

25

CP

18

CP

17

VP

UM

P_G

OO

D

BR

EV

2

CP

16

LC

PS

_F

TD

O

CP

19

CP

20

CP

21

CP

22

CP

23

VJT

AG

_G

OO

D

BR

EV

0

CP

0

CP

29

FP

3_LE

D1

LC

PS

_F

TR

ST

_N

CP

1

JT

AG

EN

B_N

JT

AG

EN

B_N

FP

3_LE

D0

CP

2C

P3

CP

7C

P6

CP

5

CP

4

FP

3_LE

D3

FP

3_LE

D2

FP

3_LE

D4

BR

EV

1

TR

ST

EN

B_N

CP

15

LC

PS

_F

TD

OLC

PS

_F

TD

I

LC

PS

_F

TC

kLC

PS

_F

TM

S

LC

PS

_F

TD

I

LC

PS

_F

TC

k

LC

PS

_F

TM

S

V3

V3

F

V2V

5F

V3

V3

F

V3

V3

F

V3P

3

V3

V3

F

LC

PS

_F

TM

SLC

PS

_F

TC

kLC

PS

_F

TD

I

LC

PS

_F

TD

O

CP10

CP11

CP12

PASS/FA

IL

(TDI_IN)(TMS_IN)(TCK_IN)(NTRST_IN)

ACTIVITY

ON

APA150-TQ100

LEDs

LCPS JTAG Signals

A1

2

OE

11

Y1

6

VC

C8

GN

D4

U58A

NC

7W

V125K

8X

-US

8

U58A

NC

7W

V125K

8X

-US

8

R5

16

39

R-0

60

3R

51

63

9R

-06

03

A1

2

OE

11

Y1

6

VC

C8

GN

D4

U6

0A

NC

7W

V125K

8X

-US

8

U6

0A

NC

7W

V125K

8X

-US

8

31

24

R GD

13

HS

MF

-C165

R GD

13

HS

MF

-C165

R5

10

2K

2-0

603

R5

10

2K

2-0

603

D14

LT

ST

-C190Y

KT

D14

LT

ST

-C190Y

KT

IO2

2IO

33

IO4

4

IO5

5

IO6

6

IO7

7

IO8

8

IOG

LM

X1

10

GL1

11

NPECL113

PPECL115

GL216

IO18

18

IO19

19

IO2020

IO2121

IO2222

IO2323

IO2424

GND11

GND99

GND2525

GND3838

GND4040

AGND1212

IO2727

IO2828

IO2929

IO3030

IO3131

IO3232

IO3333

IO3434

IO3535

IO3636

IO4141

IO4242

IO4343

IO4444

IO4545

IO4646

AGND6464

GND5151

GND6767

GND7575

GND8686

GND8888

IO74

74

IO73

73

IO72

72

IO71

71

IO70

70

IO69

69

GLM

X2/IO

66

GL465

NPECL263

PPECL261

GL360

IO59

59

IO58

58

IO57

57

VP

P52

VP

N53

TC

K47

TD

I48

TM

S49

TD

O54

TR

ST

55

RC

K56

AVDD1414

VDD1717

VDD3737

AVDD6262

VDD6868

VDD6989

IO9999

IO9898

IO97

97

IO96

96

IO95

95

IO94

94

IO93

93

IO92

92

IO9191

IO9090

IO8585

IO84

84

IO83

83

IO82

82

IO81

81

IO80

80

IO79

79

IO78

78

IO77

77

VDDP2626

VDDP3939

VDDP5050

VDDP7676

VDDP8787

VDDP100100

U57

AP

A150-T

Q100

U57

AP

A150-T

Q100

R5

11

DN

L-0

60

3R

51

1D

NL

-06

03

R5

19

33

R-0

60

3R

51

93

3R

-06

03

R5

14

33

R-0

60

3R

51

43

3R

-06

03

R5

13

39

R-0

60

3R

51

33

9R

-06

03

A2

5

OE

27

Y2

3

VC

C8

GN

D4

U60B

NC

7W

V1

25

K8

X-U

S8

U60B

NC

7W

V1

25

K8

X-U

S8

R5

18

39

R-0

60

3R

51

83

9R

-06

03

R5

05

DN

L-0

60

3R

50

5D

NL

-06

03

R5

08

DN

L-0

60

3R

50

8D

NL

-06

03

D15

LT

ST

-C190K

FK

TD

15

LT

ST

-C190K

FK

T

R5

03

2K

2-0

603

R5

03

2K

2-0

603

R5

15

10

0R

-06

03

R5

15

10

0R

-06

03

A2

5

OE

27

Y2

3

VC

C8

GN

D4

U58B

NC

7W

V1

25

K8

X-U

S8

U58B

NC

7W

V1

25

K8

X-U

S8

R5

17

33

R-0

60

3R

51

73

3R

-06

03

Revision 7 27


Temperature DiodeA temperature diode is provided on the board to measure ambient temperature Figure 3-24. This is usedin battery charging and MPM applications. This diode is connected to the AT1 input of the SmartFusioncSoC.

Table 3-4 • Jumper Settings for A2F200 Programming

To Program with Built-In LCP


JP7 1 2 To select the integrated LCP

JP10 1 2 To select the SmartFusion cSoC device

Figure 3-23 • A2F200 JTAG Connections

F2_TDO

F2_TMS

TDI

VPUMPVJTAG

TRST

F2_TCK

JTAG_SEL

JTAG_SEL

V3P3_F2 V3P3_F2

V3P3_F2

C64

0.1

uF

-04

02

C64

0.1

uF

-04

02

R9 1K-0603R9 1K-0603

R13 39R-0603R13 39R-0603

C65

0.0

1u

F-0

60

3

C65

0.0

1u

F-0

60

3

1

2

3

JP10JP10

R15

1K-0603

R15

1K-0603

C66

0.1uF-0402

C66

0.1uF-0402

TCK P18

TRSTB P22

TMSP20

TDIP17

TDOP21 JTAGSEL R16

VJTAGM19 VPP M21

JTAG SIGNALS

U64-6

A2F200M3F-FGG484

JTAG SIGNALS

U64-6

A2F200M3F-FGG484

R8 1K-0603R8 1K-0603

R14

510R-0603

R14

510R-0603

Figure 3-24 • Temperature Diode

ATGND0

AT1

Mfr P/N :MMBT3904LT1Mfr:Infineon Technologies

TO DUT

1

32

Q2

MMBT3904LT1

Q2

MMBT3904LT1

28 Revision 7


Mixed Signal HeaderThe mixed signal header can be obtained from Samtec, using the following part numbers:

• Mother Board Header 2X50 50 mil pitch: Samtec FTSH-150-04-L-D-RA (populated in the evaluation board)

• Daughter Board Header 2X50 50 mil pitch: Samtec CLP-150-02-L-DH

The detailed instructions given below must be followed to ensure the correct orientation and insertion intothe mother board.

Figure 3-25 (top view) indicates the orientation of the mixed signal headers on the mother board anddaughter board.

Figure 3-25 • Top View of Mixed Signal Headers Correct Orientation

Mother Board

Daughter Board

Pin 1 Pin 2

Revision 7 29


Ensure that the header is placed such that a full insertion is possible between the two headers(Figure 3-26).

When designing a daughter board to plug into an A2F-EVAL-KIT:

• Ensure the CLP header edge is lined up against the edge of the board.

• This will provide maximum insertion into the SmartFusion evaluation board.

When designing a mother board for an existing daughter board (MPM DB, for example):

• Ensure that the length, denoted by XX, is kept less than 150 mils.

• Use the SmartFusion Evaluation Kit PCB files(www.microsemi.com/soc/download/rsc/?f=A2F_EVAL_KIT_BF).

Note: XX is the critical length. Ensure that the connector is placed close enough so there is a good connection with the mating connector. This is applicable when designing the daughter board or the mother board.

Figure 3-26 • Correct Insertion of Daughter Board

Mother Board Daughter Board

FTSH HDR CLP HDR

Correct

Mother Board Daughter Board

FTSH HDR CLP HDR

Incorrect

Good insertion

of the pins

Not enough insertion

of the pins

XX

XX

The CLP header should be

lined up to the board edge.

The CLP Header is not lined up

30 Revision 7


Pinout DefinitionTable 3-5 provides the pinout definition for the mixed signal header.

Table 3-5 • Pinout Definition

J21-Pin Net NamePin

Number Description J21-Pin Net NamePin

Number Description

1 5V Power Power 2 5V Power Power

3 5V Power Power 4 5V Power Power

5 DGND DGND Digital ground 6 DGND DGND Digital ground

7 MSS_GP_IO_0 V1 MSS I/Os1 8 MSS_GP_IO_1 R3 MSS I/Os1

9 MSS_GP_IO_2 W1 MSS I/Os1 10 MSS_GP_IO_3 Y1 MSS I/Os1

11 MSS_GP_IO_4 AA1 MSS I/Os1 12 DGND DGND Digital ground

13 MSS_GP_IO_5 U2 MSS I/Os1 14 MSS_GP_IO_6 V2 MSS I/Os1

15 DGND DGND Digital ground 16 MSS_GP_IO_7 W2 MSS I/Os1

17 MSS_GP_IO_8 T3 MSS I/Os1 18 MSS_GP_IO_9 V3 MSS I/Os1

19 MSS_GP_IO_10 U3 MSS I/Os1 20 DGND DGND Digital ground

21 MSS_GP_IO_11 T4 MSS I/Os1 22 MSS_GP_IO_12 AA2 MSS I/Os1

23 DGND DGND Digital ground 24 MSS_GP_IO_13 AB2 MSS I/Os1

25 MSS_GP_IO_14 AB3 MSS I/Os1 26 MSS_GP_IO_15 Y3 MSS I/Os1

27 F2-200-IO_0 E3 FPGA I/Os1 28 DGND DGND Digital ground

29 F2-200-IO_1 F3 FPGA I/Os1 30 F2-200-IO_2 G4 FPGA I/Os1

31 DGND DGND Digital ground 32 F2-200-IO_3 H5 FPGA I/Os1

33 F2-200-IO_4 H6 FPGA I/Os1 34 F2-200-IO_5 J6 FPGA I/Os1

35 F2-200-IO_6 B22 FPGA I/Os1 36 DGND Digital ground

37 F2-200-IO_7 C22 FPGA I/Os1 38 F2-200-IO_8 F1 FPGA I/Os1

39 PWM0 E22 Has External RC*1 40 PWM1 F22 Has External RC*1


43 AGND AGND Analog ground 44 AGND AGND Analog ground

45 DACOUT0 V7 SDD02 46 DACOUT1 Y17 SDD12


49 AC2 AB13 CM22 50 AT2 AB12 TM22

51 AGND AGND Analog ground 52 ATGND1 GNDTM12

53 AC3 AA11 CM32 54 AT3 Y12 TM32

55 AGND AGND Analog ground 56 AGND Analog ground

57 NC NC NC 58 NC NC NC

59 AGND AGND Analog ground 60 NC NC NC

Notes:

1. Digital signal.

2. Analog signal.

Revision 7 31


61 AV1_1 W9 ABPS22 62 AV2_1 AB7 ABPS32


65 AV1_3 W12 ABPS62 66 AV2_3 Y11 ABPS72




73 ADC2 V9 ADC2 74 ADC3 AB8 ADC3


77 ADC4 U12 ADC4 78 ADC5 V12 ADC5


81 ADC6 V11 ADC62 82 ADC7 T12 ADC72





91 AC1 U9 CM12 92 AGND AGND Analog ground



97 3.3V Power Power 98 3.3V Power Power

99 3.3V Power Power 100 3.3V Power Power

Table 3-5 • Pinout Definition

J21-Pin Net NamePin

Number Description J21-Pin Net NamePin

Number Description

Notes:

1. Digital signal.

2. Analog signal.

32 Revision 7

4 – Pin List

Table 4-1 gives a pin list applicable to the SmartFusion A2F200M3F-FGG484 device.

Table 4-1 • Pin List

A2F200 Pin Number A2F200 Pin Name Board Signal Name

A1 GND1 GND

A2 NC2 NC

A3 NC5 NC

A4 GND7 GND

A5 EMC_CS0_N/GAB0/IO01NDB0V0 NC

A6 EMC_CS1_N/GAB1/IO01PDB0V0 NC

A7 GND8 GND

A8 EMC_AB[0]/IO04NDB0V0 NC

A9 EMC_AB[1]/IO04PDB0V0 NC

A10 GND2 GND

A11 NC1 NC


A13 GND3 GND

A14 EMC_AB[12]/IO10NDB0V0 NC


A16 GND4 GND

A19 GND5 GND

A20 NC3 NC

A21 NC4 NC

A22 GND6 GND

AA1 GPIO_4/IO43RSB4V0 MSS_GP_IO_4

AA2 GPIO_12/IO37RSB4V0 MSS_GP_IO_12

AA3 MAC_MDC/IO48RSB4V0 FPGA_ENA_MDC

AA4 MAC_RXER/IO50RSB4V0 FPGA_ENA_RXER

AA5 MAC_TXD[0]/IO56RSB4V0 FPGA_ENA_TXD0

AA6 ABPS0 V10P

AA7 TM1 AT1

AA8 ADC1 NC

AA9 GND15ADC1 AGND

Revision 7 33

Pin List


AA10 GND33ADC10 AGND

AA11 CM3 AC3

AA12 GNDTM1 ATGND1

AA13 ADC10 NC

AA14 ADC9 NC

AA16 MAINXIN AGND (Y1,C48)

AA17 MAINXOUT AGND (Y1,C50)

AA18 LPXIN AGND (Y2,C51)

AA19 LPXOUT AGND (Y2,C52)

AA20 NC6 NC

AA21 NC7 NC

AA22 SPI_1_CLK/GPIO_26 GND

AB1 GND9 GND

AB2 GPIO_13/IO36RSB4V0 MSS_GP_IO_13

AB3 GPIO_14/IO35RSB4V0 MSS_GP_IO_14

AB4 GND11 GND

AB5 PCAP C49

AB6 NCAP C49

AB7 ABPS3 AV2_1

AB8 ADC3 ADC3

AB9 GND15ADC0 AGND

AB10 VCC33ADC1 V3P3A

AB11 VAREF1 VAREF_OUT

AB12 TM2 AT2

AB13 CM2 AC2

AB14 ABPS4 V3P3

AB15 GNDAQ1 AGND

AB16 GNDMAINXTAL AGND

AB17 GNDLPXTAL AGND

AB18 VCCLPXTAL V3P3A

AB19 VDDBAT GND

AB20 PTBASE PTBASE

AB21 NC8 NC

Table 4-1 • Pin List (continued)

34 Revision 7



AB22 GND10 GND

B1 EMC_DB[15]/GAA2/IO71PDB5V0 NC

B2 GND12 GND

B5 VCCFPGAIOB0_3 V3P3_F2

B6 EMC_RW_N/GAA1/IO00PDB0V0 NC


B9 EMC_BYTEN[0]/GAC0/IO02NDB0V0 NC

B10 EMC_AB[2]/IO05NDB0V0 NC

B11 EMC_AB[3]/IO05PDB0V0 NC








B19 GBB0/IO18NDB0V0 LED1_N

B20 GBB1/IO18PDB0V0 LED2_N

B21 GND13 GND

B22 GBA2/IO20PDB1V0 F2-200-IO_6

C1 EMC_DB[14]/GAB2/IO71NDB5V0 NC

C2 NC9 NC

C3 NC11 NC

C6 EMC_CLK/GAA0/IO00NDB0V0 NC

C9 EMC_BYTEN[1]/GAC1/IO02PDB0V0 NC

C10 EMC_OEN1_N/IO03PDB0V0 NC

C11 GND14 GND

C12 VCCFPGAIOB0_5 V3P3_F2

C13 EMC_AB[8]/IO08NDB0V0 NC


C15 EMC_AB[17]/IO12PDB0V0 NC




Revision 7 35

Pin List


C18 EMC_AB[23]/IO15PDB0V0 NC

C19 GBA0/IO19NPB0V0 LED3_N

C20 NC10 NC

C21 GBC2/IO21PDB1V0 LED6_N

C22 GBB2/IO20NDB1V0 F2-200-IO_7

D1 GND15 GND

D2 EMC_DB[12]/IO70NDB5V0 NC

D3 EMC_DB[13]/GAC2/IO70PDB5V0 NC

D4 NC14 NC

D5 NC15 NC

D6 GND19 GND

D9 GND20 GND

D10 EMC_OEN0_N/IO03NDB0V0 NC

D11 EMC_AB[10]/IO09NDB0V0 NC

D12 EMC_AB[11]/IO09PDB0V0 NC


D14 GND16 GND

D15 GBC1/IO17PPB0V0 OLED_D/C#


D17 GND17 GND

D18 GBA1/IO19PPB0V0 NC

D19 NC12 NC

D20 NC13 NC

D21 IO21NDB1V0 LED7_N

D22 GND18 GND

E1 GFC2/IO67PPB5V0 NC

E2 VCCFPGAIOB5_1 V3P3_F2

E3 GFA2/IO68PDB5V0 F2-200-IO_0

E4 GND22 GND

E5 NC18 NC

E6 GNDQ1 GND


E9 NC19 NC


36 Revision 7




E11 EMC_AB[4]/IO06NDB0V0 NC

E12 EMC_AB[5]/IO06PDB0V0 NC


E14 GBC0/IO17NPB0V0 NC

E15 NC16 NC


E17 VCOMPLA1 NC

E19 GND21 GND

E20 NC17 NC


E22 IO22NDB1V0 F2-200-PWM0

F1 GFB1/IO65PPB5V0 F2-200-IO_8

F2 IO67NPB5V0 RMII_50MHZ_CLK

F3 GFB2/IO68NDB5V0 F2-200-IO_1

F4 EMC_DB[10]/IO69NPB5V0 NC

F5 VCCFPGAIOB5_2 V3P3_F2

F6 VCCPLLA V1P5_DUT (VCCPLA)

F7 VCOMPLA GND

F8 NC23 NC

F9 NC24 NC

F10 NC20 NC

F11 NC21 NC

F12 NC22 NC

F13 EMC_AB[20]/IO14NDB0V0 NC

F14 EMC_AB[21]/IO14PDB0V0 NC

F15 GNDQ2 GND

F16 VCCPLA NC

F18 VCCFPGAIOB1_2 V3P3_F2

F19 IO23NDB1V0 NC

F22 IO22PDB1V0 F2-200-PWM1

G1 GND23 GND

G2 GFB0/IO65NPB5V0 NC


Revision 7 37

Pin List


G3 EMC_DB[9]/GEC1/IO63PDB5V0 NC

G4 GFC1/IO66PPB5V0 F2-200-IO_2

G5 EMC_DB[11]/IO69PPB5V0 NC

G6 GNDQ4 GND

G7 NC25 NC

G8 GND28 GND

G9 VCCFPGAIOB0_11 V3P3_F2

G10 GND24 GND


G12 GND25 GND


G14 GND26 GND


G16 GNDQ3 GND

G19 GCA2/IO23PDB1V0 SWITCH1

G20 IO24NDB1V0 SWITCH2

G21 GCB2/IO24PDB1V0 LED8_N

G22 GND27 GND

H1 EMC_DB[7]/GEB1/IO62PDB5V0 NC

H2 VCCFPGAIOB5_3 V3P3_F2

H3 EMC_DB[8]/GEC0/IO63NDB5V0 NC

H4 GND33 GND

H5 GFC0/IO66NPB5V0 F2-200-IO_3

H6 GFA1/IO64PDB5V0 F2-200-IO_4

H7 GND34 GND

H8 VCC4 V1P5_DUT

H9 GND35 GND

H10 VCC1 V1P5_DUT

H11 GND29 GND

H12 VCC2 V1P5_DUT

H13 GND30 GND

H14 VCC3 V1P5_DUT

H15 GND31 GND


38 Revision 7




H17 IO25NDB1V0 LED4_N

H18 GCC2/IO25PDB1V0 NC

H19 GND32 GND

H20 GCC0/IO26NPB1V0 LED5_N


H22 GCB0/IO27NDB1V0 NC

J1 EMC_DB[6]/GEB0/IO62NDB5V0 NC

J2 EMC_DB[5]/GEA1/IO61PDB5V0 NC

J3 EMC_DB[4]/GEA0/IO61NDB5V0 NC

J4 EMC_DB[3]/GEC2/IO60PPB5V0 NC

J5 VCCFPGAIOB5_4 V3P3_F2

J6 GFA0/IO64NDB5V0 F2-200-IO_5


J8 GND40 GND

J9 VCC8 V1P5_DUT

J10 GND36 GND

J11 VCC5 V1P5_DUT

J12 GND37 GND

J13 VCC6 V1P5_DUT

J14 GND38 GND

J15 VCC7 V1P5_DUT

J16 GND39 GND


J19 GCA0/IO28NDB1V0 J22.1

J20 GCA1/IO28PDB1V0 J22.2

J21 GCC1/IO26PPB1V0 J22.3

J22 GCB1/IO27PDB1V0 J22.4

K1 GND41 GND

K2 EMC_DB[0]/GEA2/IO59NDB5V0 NC

K3 EMC_DB[1]/GEB2/IO59PDB5V0 NC

K5 EMC_DB[2]/IO60NPB5V0 NC

K7 GND46 GND


Revision 7 39

Pin List


K8 VCC12 V1P5_DUT

K9 GND47 GND

K10 VCC9 V1P5_DUT

K11 GND42 GND

K12 VCC10 V1P5_DUT

K13 GND43 GND

K14 VCC11 V1P5_DUT

K15 GND44 GND

K16 VCCFPGAIOB1_6 V3P3_F2

K18 GDA1/IO31PDB1V0 NC

K19 GDA0/IO31NDB1V0 J22.5

K20 GDC1/IO29PDB1V0 NC

K21 GDC0/IO29NDB1V0 NC

K22 GND45 GND

L4 GND52 GND

L7 VCCFPGAIOB5_10 V3P3_F2

L8 GND53 GND

L9 VCC16 V1P5_DUT

L10 GND48 GND

L11 VCC13 V1P5_DUT

L12 GND49 GND

L13 VCC14 V1P5_DUT

L14 GND50 GND

L15 VCC15 V1P5_DUT

L16 GND51 GND

L17 GNDQ5 GND

L18 GDA2/IO33NDB1V0 NC

L19 VCCFPGAIOB1_7 V3P3_F2

L20 GDB1/IO30PDB1V0 NC

L21 GDB0/IO30NDB1V0 NC

L22 GDC2/IO32PDB1V0 NC

M3 VCCFPGAIOB5_6 V3P3_F2

M5 GNDQ6 GND


40 Revision 7



M7 GND58 GND

M8 VCC20 V1P5_DUT

M9 GND59 GND

M10 VCC17 V1P5_DUT

M11 GND54 GND

M12 VCC18 V1P5_DUT

M13 GND55 GND

M14 VCC19 V1P5_DUT

M15 GND56 GND

M16 VCCFPGAIOB1_8 V3P3_F2

M17 NC26 NC

M18 GDB2/IO33PDB1V0 NC

M19 VJTAG VJTAG

M20 GND57 GND

M21 VPP VPUMP

M22 IO32NDB1V0 NC

N1 GND60 GND

N5 VCCFPGAIOB5_7 V3P3_F2


N8 GND65 GND

N9 VCC24 V1P5_DUT

N10 GND61 GND

N11 VCC21 V1P5_DUT

N12 GND62 GND

N13 VCC22 V1P5_DUT

N14 GND63 GND

N15 VCC23 V1P5_DUT

N17 NC27 NC


N20 GNDENVM GND

N21 NC28 NC

N22 GND64 GND

P3 GNDRCOSC GND


Revision 7 41

Pin List


P4 GND70 GND

P5 NC29 NC

P6 NC30 NC

P7 GND71 GND

P8 VCC28 V1P5_DUT

P9 GND72 GND

P10 VCC25 V1P5_DUT

P11 GND66 GND

P12 VCC26 V1P5_DUT

P13 GND67 GND

P14 VCC27 V1P5_DUT

P15 GND68 GND

P16 VCCFPGAIOB1_10 V3P3_F2

P17 TDI TDI

P18 TCK F2_TCK

P19 GND69 GND

P20 TMS F2_TMS

P21 TDO F2_TDO

P22 TRSTB TRST

R1 MSS_RESET_N MSS_RESET_N

R2 VCCFPGAIOB5_9 V3P3_F2

R3 GPIO_1/IO46RSB4V0 MSS_GP_IO_1

R4 NC35 NC

R5 NC36 NC

R6 NC37 NC

R7 NC38 NC

R8 GND76 GND

R9 VCC32 V1P5_DUT

R10 GND73 GND

R11 VCC29 V1P5_DUT

R12 GND74 GND

R13 VCC30 V1P5_DUT

R14 GND75 GND


42 Revision 7



R15 VCC31 V1P5_DUT

R16 JTAGSEL JTAG_SEL

R17 NC31 NC

R18 NC32 NC

R19 NC33 NC

R21 VCCFPGAIOB1_11 V3P3_F2

R22 NC34 NC

T1 GND77 GND

T3 GPIO_8/IO39RSB4V0 MSS_GP_IO_8

T4 GPIO_11/IO57RSB4V0 MSS_GP_IO_11

T5 GND80 GND

T6 MAC_CLK GND

T8 VCC33SDD0 V3P3A

T9 VCC15A V1P5A

T10 GNDAQ0 AGND

T11 GND33ADC01 AGND

T12 ADC7 ADC7

T13 AT4 NC

T14 VAREF2 NC

T15 VAREFOUT VAREF_OUT

T17 SPI_1_DO/GPIO_24 NC

T18 GND78 GND

T22 GND79 GND

U1 GND81 GND

U2 GPIO_5/IO42RSB4V0 MSS_GP_IO_5

U3 GPIO_10/IO58RSB4V0 MSS_GP_IO_10

U5 MAC_RXD[1]/IO53RSB4V0 FPGA_ENA_RXD1

U6 NC39 NC

U7 VCC33AP V3P3A

U8 VCC33N AGND

U9 CM1 AC1

U10 VAREF0 VAREF_OUT

U11 GND33ADC11 AGND


Revision 7 43

Pin List


U12 ADC4 ADC4

U13 ATGND_02 NC

U14 ADC11 NC

U15 GNDVAREF AGND

U16 VCC33SDD1 V3P3A

U17 SPI_0_DO/GPIO_16 SPI_SI

U18 UART_0_RXD/GPIO_21 RXD_0_IN

U20 I2C_1_SCL/GPIO_31 NC

U21 I2C_0_SCL/GPIO_23 OLED_SCL

U22 GND82 GND

V1 GPIO_0/IO47RSB4V0 MSS_GP_IO_0

V2 GPIO_6/IO41RSB4V0 MSS_GP_IO_6

V3 GPIO_9/IO38RSB4V0/ADC3 MSS_GP_IO_9

V4 MAC_MDIO/IO49RSB4V0 FPGA_ENA_MDIO

V5 MAC_RXD[0]/IO54RSB4V0 FPGA_ENA_RXD0

V6 GND84 GND

V7 SDD0 DACOUT0

V8 ABPS1 V1P5

V9 ADC2 ADC2

V10 VCC33ADC0 V3P3A

V11 ADC6 ADC6

V12 ADC5 ADC5

V13 ABPS5 AV2_2

V14 ADC8 NC

V16 NC40 NC

V17 GND83 GND

V18 SPI_0_DI/GPIO_17 SPI_SO

V19 SPI_1_DI/GPIO_25 NC

V20 UART_1_TXD/GPIO_28 NC

V21 I2C_0_SDA/GPIO_22 OLED_SDA

V22 I2C_1_SDA/GPIO_30 NC

W1 GPIO_2/IO45RSB4V0 MSS_GP_IO_2

W2 GPIO_7/IO40RSB4V0 MSS_GP_IO_7


44 Revision 7



W3 GND86 GND

W4 MAC_CRSDV/IO51RSB4V0 FPGA_ENA_CRS

W5 MAC_TXD[1]/IO55RSB4V0 FPGA_ENA_TXD1

W6 NC41 NC

W7 GNDA0 AGND

W8 TM0 AT0

W9 ABPS2 AV1_1

W10 GND33ADC02 AGND

W11 VCC15ADC1 V1P5A

W12 ABPS6 AV1_3

W13 AC4 NC

W14 AV2_4 NC

W16 GNDA1 AGND

W17 PU_N RTC_SW

W18 GNDSDD1 AGND

W19 SPI_0_CLK/GPIO_18 SPI_SCK

W20 GND85 GND

W21 SPI_1_SS/GPIO_27 NC

W22 UART_1_RXD/GPIO_29 NC

Y1 GPIO_3/IO44RSB4V0 MSS_GP_IO_3

Y3 GPIO_15/IO34RSB4V0 MSS_GP_IO_15

Y4 MAC_TXEN/IO52RSB4V0 FPGA_ENA_TXEN

Y7 CM0 AC0

Y8 GNDTM0 ATGND0

Y9 ADC0 ADC0

Y10 VCC15ADC0 V1P5A

Y11 ABPS7 AV2_3

Y12 TM3 AT3

Y13 AV1_4 NC

Y16 VCCMAINXTAL V3P3A

Y17 SDD1 DACOUT1

Y18 PTEM V1P5_INT

Y19 VCC33A V3P3A


Revision 7 45

Pin List


Y20 SPI_0_SS/GPIO_19 SPI_CS_N

Y22 UART_0_TXD/GPIO_20 TXD_0_OUT


46 Revision 7

5 – Board Stackup

Board Stack-UpThe SmartFusion Evaluation Kit board is built on a 6-layer printed circuit board (PCB). The silkscreen isprovided in Figure 5-2 on page 48. The full PCB design layout is provided on the SmartFusion EvaluationKit page of the Microsemi SoC Products Group website:

www.microsemi.com/soc/products/hardware/devkits_boards/smartfusion_dev.aspx.

To view the PCB design layout files, you can use Allegro Free Physical Viewer, which can bedownloaded from the Cadence website Allegro download page:

www.cadence.com/products/pcb/Pages/Downloads.aspx.

The layers are arranged in the following order:

• Layer1: Top Signal

• Layer2: GND1

• Layer3: PWR1

• Layer4: PWR2

• Layer5: GND2

• Layer6: Bottom Signal

Figure 5-1 shows the stack-up.

Figure 5-1 • A2F-EVAL-KIT PCB Layer Stack-Up

Revision 7 47

http://www.microsemi.com/soc/products/hardware/devkits_boards/smartfusion_dev.aspx

http://www.cadence.com/products/pcb/Pages/Downloads.aspx

Board Stackup

Figure 5-2 shows the silkscreen top view.

Figure 5-2 • A2F-EVAL-KIT Top Silk-Screen

48 Revision 7

6 – Demo Design

This chapter describes how to run the Webserver demo design on the SmartFusion Evaluation Kit. TheSmartFusion Evaluation Kit comes with a preloaded Webserver demo design. If the board is notpreprogrammed, the programming file and the source files for the demo are provided on the SmartFusionEvaluation Kit page:

www.microsemi.com/soc/products/hardware/devkits_boards/smartfusion_eval.aspx.

The programming file for the demo is provided as a standalone zip file under the SmartFusion EvaluationKit Quickstart Card. The source files are provided with the SmartFusion Webserver Demo Using uIP andFreeRTOS User’s Guide.

Jumper Settings for Demo DesignPrior to powering up the A2F-EVAL-KIT for the first time, make sure the jumpers are set as shown in theTable 6-1.

Running the Demo DesignConnect one end of the USB mini B cable to the USB connection, J14 (labeled as USB2) on the A2F-EVAL-KIT board. Connect the other end of the USB cable to the PC you will use for testing. Theboard receives power from USB. LED1 lights up, indicating the board is powered up. The D11 LED alsolights up, indicating UART link establishment. Connect an ethernet cable from the local area network toJ10, the A2F-EVAL-KIT ethernet jack.

This demo provides you the flexibility to select demo options using switches or serial terminal emulationprograms like HyperTerminal or PuTTy. With a USB driver properly installed, and correct COM port andcommunication settings selected, you can use the serial terminal emulation program to communicatewith a design running on a SmartFusion cSoC.

Configure the serial terminal emulation program which is available on your PC with the following settings:

• Bits per second: 57600

• Data bits: 8

• Parity: None

• Stop bits: 1

• Flow control: None

Table 6-1 • Manufacturing Test Jumper Settings

Jumper Location Purpose Setting

J6 2 pins next to the Ethernet jack 3.3 V regulator 1-2

JP6 Next to the PU_N switch VRPSM volatage option 2-3

JP7 Right side of board Input selecting option 1-2

JP10 Right side of board JTAG programming option 1-2

JP11 Right side of board Access to LED5 1-2




J24 Bottom right side of board VAREFOUT/VAREF Header 1-2, 3-4

Revision 7 49

www.microsemi.com/soc/products/hardware/devkits_boards/smartfusion_eval.aspx

http://www.microsemi.com/soc/documents/SmartFusion_Webserver_uIPRTOS_UG.PDF


Demo Design

Refer to the Configuring Serial Terminal Emulation Programs Tutorial for configuring the HyperTerminal,Tera Term, or PuTTY.

Press switch SW3 (RESET) to start the demo. If the board is programmed correctly, a welcome messageis displayed on the OLED as shown in Figure 6-1 on page 50.

The OLED then displays the SmartFusion Menu, as shown in Figure 6-2.

If you cannot see the display on the OLED, recheck the jumper settings, and if required, program theSmartFusion cSoC with the provided programming file.

The message on the OLED (see Figure 6-2) indicates that you can either press switch SW1 on the kit toselect Multimeter mode, or press switch SW2 to scroll the menu on OLED.

Figure 6-1 • SmartFusion Welcome Display on OLED

Figure 6-2 • SmartFusion Menu Display on OLED

50 Revision 7

http://www.microsemi.com/soc/documents/Configuring_Serial_Terminal_Emulation_Programs.pdf

http://www.microsemi.com/soc/documents/Configuring_Serial_Terminal_Emulation_Programs.pdf


The serial terminal emulation program displays a welcome message and the SmartFusion Play Menu foruser selection as shown in Figure 6-3. Use the keyboard to press ‘0’ to select the Multimeter mode, ‘1’ toselect Webserver mode, or ‘2’ to select LED Test.

Multimeter ModePress switch SW1 to select the Multimeter mode. OLED displays the values of the POT voltage, POTcurrent, and external temperature read by the analog computing engine (ACE) of SmartFusion cSoC.Rotate the POT provided on the SmartFusion evaluation board to observe the change in the POT valuesdisplayed on the OLED. Press SW1 to go back to the main menu.

The same Multimeter mode can be selected by pressing 0 in the serial terminal emulation program. Thisdisplays the values of the POT voltage, POT current, and external temperature on the serial terminalemulation program like HyperTerminal.

Webserver ModePress switch SW2 to scroll the menu and then press switch SW1 to select the Webserver mode. Thisdisplays the IP address captured by DHCP from the network on OLED and the serial terminal emulationprogram.

The Webserver mode can also be selected by pressing ‘1’ in the serial terminal emulation program.

Note: To capture the dynamic IP from network, the local area network must be running a DHCP serverthat assigns an IP address to the Webserver on the board. The network firewalls must not block theboard webserver.

Figure 6-3 • Serial Terminal Emulation Program (HyperTerminal) Window

Revision 7 51

Demo Design

Enter the captured IP address in the Internet Explorer address bar and press Enter to browse theWebserver utility. Figure 6-4 shows the SmartFusion Webserver home page.

Note: Internet Explorer version 6.0 should be used to run the Webserver utility with proper web pagevisibility. Also the PC Ethernet card link speed should be in Auto Detect mode or fixed to 100 Mbpsspeed.

Figure 6-4 • SmartFusion Webserver Home page

52 Revision 7


Real Time Data DisplaySelect Real Time Data Display on the Webserver home page. It displays the voltage, current, andtemperature values in real time. The web page refreshes periodically, and displays the updated values ofvoltage, current, and temperature. Vary the potentiometer on the board and observe the change in thevoltage and current values. Click the Home button to go back to Home page. Figure 6-5 shows theSmartFusion Webserver Real Time Display web page.

LED TestPress switch SW2 to scroll the menu and then press SW1 to select LED test. Observe the blinking ofLEDs available on the SmartFusion Evaluation Kit.

Refer to the SmartFusion Webserver Demo Using uIP and FreeRTOS User’s Guide for step by stepprocedure to run the demo and for complete features of webserver demo.

Figure 6-5 • SmartFusion Webserver Real Time Display Web Page

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7 – Manufacturing Test

A2F-EVAL-KIT-2 Board Testing ProceduresThis chapter defines and describes the specific A2F-EVAL-KIT board testing procedures. Instructions forrunning the A2F-EVAL-KIT board tests and the steps needed to set up the test environment are outlinedin the following sections.

Associated files for this procedure can be downloaded from the Microsemi SoC Products Group website:

www.microsemi.com/soc/download/rsc/?f=A2F_EVAL_KIT_Mfg_PF.

Jumper Settings for the Board TestTable 7-1 lists all the jumpers that need to be set on the board for performing the tests. In case any of thetests in the following section do not work as expected, double-check Table 7-1.

Installing the A2F-EVAL-KIT Board USB Serial Driver1. Download and extract all the files stored in the CP210x_driver.zip archive from the Microsemi

SoC Products Group website.

2. Double-click on the file named CP210x_VCP_Win2K_XP_S2K3.exe.

3. Choose the Install option in the Install Wizard and select Yes for the licensing agreement.

4. Restart the computer on which the driver was installed. After restart, the driver can be used tocommunicate with A2F-EVAL-KIT board.

Hooking up the Board and UART CableConnect one end of USB mini B cable to the USB connection, J14 (labeled as USB2 in Figure 7-1 onpage 56) on the A2F-EVAL-KIT board. Connect the other end of the USB cable to the PC you will use fortesting.

The board receives power from USB. LED1 lights up, indicating the board is powered up. The D11 LEDalso lights up, indicating UART link establishment.

Table 7-1 • Manufacturing Test Jumper Settings

Jumper Pin (From) Pin (To)

JP6 2 3

JP7 1 2

JP10 1 2

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Manufacturing Test

Hooking Up the Board and Ethernet CableConnect an Ethernet cable from the local area network to J10, the A2F-EVAL-KIT Ethernet jack.

Note: For the board Ethernet test to pass, the local network must be running a DHCP server that assignsan IP address to the web server on the board. Network firewalls must not block the web server.

Hooking up the A2F-EVAL-KIT Board Built-in Programmer to PCConnect the second mini USB cable to connection J13 on the board (labeled USB1 in Figure 7-1). Plugin the second side of the cable to the PC USB port. This establishes connection to the built-inprogramming circuit (FlashPro3) on the board, programming the A2F-EVAL-KIT board (SmartFusioncSoC).

Figure 7-1 • Board Manufacturing Test Setup

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1. Open the FlashPro programming software (Figure 7-2).

Figure 7-2 • FlashPro New Project Setup

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Manufacturing Test

2. Create a new programming project (Figure 7-3).

3. Select the option Single Device when choosing the programming mode

4. Click the Configure Programmer button. This makes the Load Existing Programming Filebutton available.

5. Browse the PC file system to find the A2F-EVAL-KIT.stp programming file. Click Open to selectthe A2F-EVAL-KIT.stp file (Figure 7-4).

6. Click the Program button to program the A2F-EVAL-KIT board.

Figure 7-3 • New Project Creation

Figure 7-4 • Selecting Manufacturing Test STAPL File

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Setting Up the Test Terminal1. Open the Windows start menu. Select All > Programs > Accessories > Communications and

select the HyperTerminal program (Figure 7-5). This opens HyperTerminal.

Figure 7-5 • HyperTerminal Program Setup

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Manufacturing Test

The Connection description window is displayed (Figure 7-6). Type in A2F-EVAL-KIT as thename of the new HyperTerminal session and click the OK.

2. The Connect To window is displayed. Select the COM4 serial connection (Figure 7-7).

Figure 7-6 • HyperTerminal Setup

Figure 7-7 • HyperTerminal Port Selection

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3. The COM4 Properties window is displayed. Select the following settings (Figure 7-8):

Bits per second = 19200

Data bits = 8

Parity = None

Stop bits = 1

Flow Control = None.

Figure 7-8 • HyperTerminal Port Settings

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4. Select File > Properties in the HyperTerminal window. Choose the Settings tab (Figure 7-9).

Figure 7-9 • HyperTerminal Properties

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5. Click the ASCII Setup button. Select the check box labeled Append line feeds to incoming lineends (Figure 7-10).

Figure 7-10 • ASCII Character Settings

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Manufacturing Test

Running the A2F-EVAL-KIT Board TestPress the button labeled RESET (SW3) on the A2F-EVAL-KIT board to start the test program.

1. The menu shown in Figure 7-11 is displayed on the terminal.

Note: If this message does not appear, try pressing button SW8 again. If the above message still does notappear, refer to the "Setting Up the Test Terminal" on page 59 and check to see that the terminalhas been set up correctly.

Figure 7-11 • Manufacturing Test Menu

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RESET Test1. Enter 0 into the terminal to begin the reset test. The resulting display should be similar to

Figure 7-12.

Figure 7-12 • Reset Test

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Manufacturing Test

2. If the menu appears correct, enter the character Y into the terminal (Figure 7-13).

Figure 7-13 • Reset Test Result

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UART Test1. Enter 1 into the terminal to begin the UART test (Figure 7-14).

Figure 7-14 • UART Test

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Manufacturing Test

2. Type the character Y into the terminal. The screen shown in Figure 7-15 should appear.

Figure 7-15 • UART Test Result

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Ethernet Test1. Enter 2 into the terminal to begin the Ethernet test. The screens shown in Figure 7-16 and

Figure 7-17 on page 70 should appear.

Figure 7-16 • Ethernet Test

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Manufacturing Test

Note: The IP address may vary in the network setup.

Figure 7-17 • Ethernet Test Result

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Analog Test1. Enter 3 into the terminal to begin the Analog test. The screen shown in Figure 7-18 should

appear.

2. Locate POT RV on the bottom, left hand corner of the board. Turn POT RV1 counter-clockwise allthe way to the left, as shown in Figure 7-19.

Figure 7-18 • Analog Test

Figure 7-19 • POT RV1

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Figure 7-20 • Analog Test Starting Results

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3. Turn POT RV clockwise all the way clockwise to the right. The display on the terminal should besimilar to Figure 7-21.

Figure 7-21 • Analog Test Ending Results

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Manufacturing Test

OLED Test1. Enter 4 into the terminal to begin the OLED test. The screen shown in Figure 7-22 is displayed.

Figure 7-22 • OLED Test Setup

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2. Check the board OLED display. If the characters ACTEL MAN TEST are displayed in the OLED,enter Y in the terminal; otherwise, enter N. If Y was entered, the screen shown in Figure 7-23 isdisplayed.

Figure 7-23 • OLED Test Results

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Manufacturing Test

RTC Test1. Enter 5 into the terminal to begin the RTC test (Figure 7-24).

Figure 7-24 • RTC Test

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2. After a few seconds, the screen shown in Figure 7-25 should appear.

Figure 7-25 • RTC Test Passed

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Manufacturing Test

SPI TestEnter 6 into the terminal to begin the SPI test. After several seconds, the screen shown in Figure 7-26should appear.

Figure 7-26 • SPI Test

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Switch/LED Test1. Enter 7 into the terminal to begin the LEDs test. The screen shown in Figure 7-27 is displayed.

Figure 7-27 • LED Test

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2. Press SW2 and LEDs D1, D2, D3, D4, D5, D6, D7, and D8 must light up. When this has occurred,press Y (Figure 7-28).

A2F-EVAL-KIT Board FailuresAll Tests outlined in "Running the A2F-EVAL-KIT Board Test" on page 64 should result in the wordsTEST PASSED being printed on the terminal. If this does not happen, or the words TEST FAILED areprinted, the test has failed.

• If the A2F-EVAL-KIT board fails any of the tests outlined in "Running the A2F-EVAL-KIT Board Test" on page 64, the board being tested is not functional.

Figure 7-28 • Switch Test

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A – List of Changes

The following table lists critical changes that were made in the current revision of the chapter.

Revision Changes Page

Revision 7(November 2012)

Modified "Power Sources" section (SAR 40094). 14

Replaced all mentions of the A2F-EVAL-KIT part number to the new A2F-EVAL-KIT-2 part number (SAR 39978).

n/a

Revision 6(February 2012)

Added new Figure 1 and modified Table 1 (SAR 36580). 5

Modified "Board Description" section and contents of Table 2 (SAR 36580). 6

Modified "Software Installation" section (SAR 36580). 7

Added new Table 1-4, Table 1-8, Table 1-9, and Table 1-10 (SAR 36580). 8, 9

Modified "I/O Pin Connections" section (SAR 36580). 13

Modified "VAREF Connections" section and modified Figure 3-1 (SAR 36580). 15

Modified "Push-Button Switches and User LEDs" section and added Figure 3-9(SAR 36580).

17, 18

Modified text placed at the top of Table 4-1 (SAR 36580). 33

Updated Figure 5-2 (SAR 36580). 48

Updated Table 6-1 (SAR 36580). 49

Revision 5(October 2011)

Modified the paragraph in "A2F-EVAL-KIT Board Failures" section (SAR 25394). 80

Corrected the link listed under "A2F-EVAL-KIT-2 Board Testing Procedures" section(SAR 25395).

55

In the "Pinout Definition" section, the description of pins 73,74,77, and 78 are set toADC2, ADC3, ADC4, and ADC5. The pins 57, 58, 60, 69, 70, 85, 86, 89, and 90 areset as not connected (NC) (SAR 30077).

31

Incorporated necessary text under "Installing the A2F-EVAL-KIT Board USB SerialDriver" section (SAR 25396).

55

Revision 4(May 2011)

The "Pinout Definition" table in the "Component Descriptions and Connections"chapter was updated (SAR 31533).

31

Revision 3(October 2010)

The "Demo Design" chapter was added (SAR 27577). 49

Reference added in the "Software Installation" section for IAR and Keil Softwaresupport to SmartFusion cSoC devices (SAR 27579).

7

Revision 1(February 2010)

The "Mixed Signal Header" section was added. 29

Note: *The part number is located on the last page of the document. The digits following the slash indicate the monthand year of publication.

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B – Product Support

Microsemi SoC Products Group backs its products with various support services, including CustomerService, Customer Technical Support Center, a website, electronic mail, and worldwide sales offices.This appendix contains information about contacting Microsemi SoC Products Group and using thesesupport services.

Customer ServiceContact Customer Service for non-technical product support, such as product pricing, product upgrades,update information, order status, and authorization.

From North America, call 800.262.1060From the rest of the world, call 650.318.4460Fax, from anywhere in the world, 650.318.8044

Customer Technical Support CenterMicrosemi SoC Products Group staffs its Customer Technical Support Center with highly skilledengineers who can help answer your hardware, software, and design questions about Microsemi SoCProducts. The Customer Technical Support Center spends a great deal of time creating applicationnotes, answers to common design cycle questions, documentation of known issues, and various FAQs.So, before you contact us, please visit our online resources. It is very likely we have already answeredyour questions.

Technical SupportVisit the Customer Support website (www.microsemi.com/soc/support/search/default.aspx) for more information and support. Many answers available on the searchable web resource include diagrams, illustrations, and links to other resources on the website.

WebsiteYou can browse a variety of technical and non-technical information on the SoC home page, at www.microsemi.com/soc.

Contacting the Customer Technical Support CenterHighly skilled engineers staff the Technical Support Center. The Technical Support Center can becontacted by email or through the Microsemi SoC Products Group website.

EmailYou can communicate your technical questions to our email address and receive answers back by email,fax, or phone. Also, if you have design problems, you can email your design files to receive assistance.We constantly monitor the email account throughout the day. When sending your request to us, pleasebe sure to include your full name, company name, and your contact information for efficient processing ofyour request.

The technical support email address is [email protected].

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Product Support

My CasesMicrosemi SoC Products Group customers may submit and track technical cases online by going to My Cases.

Outside the U.S.Customers needing assistance outside the US time zones can either contact technical support via email([email protected]) or contact a local sales office. Sales office listings can be found atwww.microsemi.com/soc/company/contact/default.aspx.

ITAR Technical SupportFor technical support on RH and RT FPGAs that are regulated by International Traffic in Arms Regulations (ITAR), contact us via [email protected]. Alternatively, within My Cases, select Yes in the ITAR drop-down list. For a complete list of ITAR-regulated Microsemi FPGAs, visit the ITAR web page.

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http://www.microsemi.com/soc/mycases/



http://www.microsemi.com/soc/company/contact/default.aspx

http://www.microsemi.com/soc/company/contact/default.aspx

http://www.microsemi.com/soc/company/contact/default.aspx#itartechsupport



http://www.microsemi.com/soc/ITAR/

Index

Ccontacting Microsemi SoC Products Group

customer service 83email 83web-based technical support 83

Cortex-M3 14Cortex-M3 processor 14customer service 83

EEthernet interface 24

Kkit contents 5

Llow-cost programmer 27

Mmanufacturing test 55, 81Microsemi SoC Products Group

email 83web-based technical support 83website 83

mixed-signal header 29

OOLED 19oscillators 21

Ppinout definition 31power sources 14product support

customer service 83email 83My Cases 84outside the U.S. 84technical support 83website 83

push-button reset 17push-button switches 17PWM circuit 16

RRealView header 26RMII clk 24

SSPI flash 20

Ttech support

ITAR 84My Cases 84outside the U.S. 84

technical support 83temperature diode 28

UUSB-to-UART 21

Wweb-based technical support 83

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s of

tortriallognd

at

MicroseOne EnWithin tSales: +Fax: +1

© 2012 Microsemi Corporation. All rights reserved. Microsemi and the Microsemi logo are trademark

Microsemi Corporation (NASDAQ: MSCC) offers a comprehensive portfolio of semiconducsolutions for: aerospace, defense and security; enterprise and communications; and indusand alternative energy markets. Products include high-performance, high-reliability anaand RF devices, mixed signal and RF integrated circuits, customizable SoCs, FPGAs, acomplete subsystems. Microsemi is headquartered in Aliso Viejo, Calif. Learn morewww.microsemi.com.

mi Corporate Headquartersterprise, Aliso Viejo CA 92656 USA

50200209-7/11.12

Microsemi Corporation. All other trademarks and service marks are the property of their respective owners.he USA: +1 (949) 380-61001 (949) 380-6136 (949) 215-4996

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Documents

SmartFusion Evaluation Kit User’s Guide · 2018-09-04 · SmartFusion Evaluation Kit User’s Guide Revision 7 9 Never put a jumper on these headers. These are prov ided to measure