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FPGA Configuration: Glossary

Bit-Stream
CCLK
Configuration
CS Pin
DataFrame
DIN Pin
DONE Pin
DOUT Pin
DOUT/BUSY Pin
FPGA
HDC Pin
Header
INIT Pin
JTAG Cable
LDC Pin
LengthCount
Multilinx Cable
Parallel cable III
Preamble
PROG Pin
READBACK
STARTUP
WRITE Pin
XChecker Cable


Bit-Stream

The bit-stream is a binary representation of an implemented FPGA design. The bit-stream is generated by the Xilinx bit generation tools (bitgen and makebits) and is denoted with the extension <.bit>. For information on creating .bit files refer to the Hardware Debugger Reference/User Guide.

CCLK

During configuration, the Configuration Clock (CCLK) is an output in Master modes or in Asynchronous Peripheral mode, but is an input in Slave mode, Synchronous Peripheral mode, Express mode, and SelectMAP/Slave Serial mode. After configuration, CCLK has a weak pull-up and can be selected as the Readback Clock. For further information on the CCLK Pin refer to The Programmable Logic Data Book.

Configuration

The process of programming Xilinx SRAM based FPGAs with a Bit-Stream is referred to as configuration. For a more detailed description of the Configuration Modes refer to The Programmable Logic Data Book.

CS Pin

The CS Pin is the Chip Enable Pin for Virtex/Spartan-II. It is only used in the SelectMAP mode. When CS is asserted (low) the device will examine the data on the Data bus. When CS is de-asserted, all CCLK transitions are ignored. For a more detailed description of the CS Pin and its use, refer to The Programmable Logic Data Book and Application Note 138.

DataFrame

A DataFrame is a block of configuration data. A configuration bit-stream contains many such frames each with a start bit and stop bits. For a detailed description of DataFrame sizes and format refer to The Programmable Logic Data Book.

DIN

During serial configuration, the DIN Pin is the serial configuration data input receiving data on the rising edge of CCLK. During parallel and peripheral configuration, DIN is the D0 input. After configuration, DIN is a user-programmable I/O Pin. For further information on the DIN Pin refer to The Programmable Logic Data Book.

DONE Pin

The DONE Pin on a Xilinx FPGA is a bidrectional signal with an optional internal pull-up resistor. As an output, it indicates the completion of the configuration process. As an input, a low level on DONE can be configured to delay the global logic initialization and the enabling of outputs. For further information on the DONE Pin refer to The Programmable Logic Data Book.

DOUT Pin

During configuration in any mode except Express and SelectMAP, the DOUT Pin is the serial configuration data output that can drive the DIN Pin of daisy-chained slaves FPGAs. DOUT data changes on the falling edge of CCLK, one-and-a-half CCLK periods after it was received at the DIN Pin. For further information on the DOUT Pin refer to The Programmable Logic Data Book.

DOUT/BUSY Pin

For Virtex/Spartan-II devices, the DOUT/BUSY pin has a dual purpose, depending on the mode the device is in. If the device is in Serial mode, it acts the same as the DOUT Pin. When the device is in SelectMAP/Slave Parallel mode, the pin acts as a handshaking signal. If BUSY is asserted (high) on a rising edge of CCLK, the data was not seen on the data bus, and should be held until the data is accepted. For a more detailed description of the DOUT/BUSY Pin and its use, refer to The Programmable Logic Data Book and Application Note 138.

DataFrame

A DataFrame is a block of configuration data. A configuration bit-stream contains many such frames each with a start bit and stop bits. For a detailed description of DataFrame sizes and format refer to The Programmable Logic Data Book.

FPGA

Xilinx Field Programmable Gate Arrays (FPGA) are SRAM based Programmable Logic Devices (PLD). FPGAs contain an array of programmable logic elements. The configuration data for the array is stored in an internal SRAM bank called the configuration memory. The configuration memory can be cleared on-the-fly with the PROG Pin or every time power is cycled. For more information on Xilinx SRAM based products refer to The Programmable Logic Data Book.

HDC Pin

High During Configuration (HDC) is driven High until the I/O go active in the Startup sequence. It is available as a control output indicating that configuration is not yet completed. After configuration, HDC is a user-programmable I/O Pin. For more information on FPGA I/O refer to The Programmable Logic Data Book.

Header

The Header is the first section of the Bit-Stream. This 40 bit section contains the 4 bit Preamble, a 24 bit LengthCount, and 12 dummy bits. For more information on the bit-stream format refer to The Programmable Logic Data Book.

INIT Pin

The INIT Pin is a quadruple function signal. Before and during configuration, INIT is a bidirectional signal. A 1k - 10k external pull-up resistor is recommended. As an active-Low open-drain output, INIT is held Low during power stabilization and internal clearing of the configuration memory. As an active-Low input, it can be used to hold the FPGA in the internal WAIT state before the start of configuration. During configuration, a Low on this output indicates that a configuration data error has occurred. After the I/O go active in the Startup sequence, INIT is a user-programmable I/O. For more information on configuration specifications and timing refer to The Programmable Logic Data Book.

JTAG Cable

See Parallel Cable III.

LDC Pin

Low During Configuration (LDC) is driven Low until the I/O go active in the Startup sequence. It is available as a control output indicating that configuration is not yet completed. After configuration, LDC is a user-programmable I/O Pin. For more information on FPGA I/O refer to The Programmable Logic Data Book.

LengthCount

The LengthCount is a 24 bit binary number embedded in the Header of the bit-stream. During configuration, the LengthCount is captured and stored in the Lengthcount Register. Every configuration data bit (one per CCLK period) is counted by the LengthCount Counter. When the LengthCount Register and the LengthCount Counter are equal, LengthCount Match is achieved. LengthCount Match is a requirement for entering the Startup sequence. For more information on the LengthCount and bit-stream format refer to The Programmable Logic Data Book.

Multilinx Cable

The Mutilinx Cable is the newest cable offered by Xilinx. It is capable of many complex functions, and can be reloaded with new firmware as it becomes available. It can be connected to the host computer in two ways: via the Serial port, or the USB port. The Multilinx cable is supported by the Hardware Debugger for Slave Serial and SelectMAP/Slave Parallel programming (as appropriate) as well as Readback Verify. It is also supported by the JTAG programmer for JTAG programming of CPLD's and FPGA's. For more information on using the Multilinx Cable refer to the Hardware Users Guide, the Hardware Debugger Reference/Users Guide, and the JTAG Programmer Guide.

Parallel Cable III

The Xilinx Parallel Cable III (model DLC5) is a serial download cable. The Parallel cable uses a serial 25-pin interface to the parallel port of a host computer and two 6-pin headers for flying-wire connectors to a target board. The Parallel cable is supported by the Hardware Debugger software for performing Slave Serial configuration of FPGAs only. The Parallel cable is also supported by the JTAG Programmer software for performing Slave Serial and Boundary Scan configuration of FPGAs, and Boundary Scan programming of CPLDs. For more information on using the Parallel cable refer to the Hardware Users Guide, the Hardware Debugger Reference/Users Guide, and the JTAG Programmer Guide.

Preamble

The Preamble is a 4 bit binary sentinel ("0010"b) used to indicate the beginning of the LengthCount in the Header portion of the Bit-Stream. At the beginning of configuration, the FPGA will ignore all data prior to the preamble, but will count the number of data bits preceding it. The LengthCount Counter will increment for every configuration data bit proceeding the preamble. For more information on configuration data refer to The Programmable Logic Data Book.

PROG Pin

The PROG, or PROGRAM, Pin is an active-Low input that forces the FPGA to clear it's configuration memory, and is used to initiate a configuration cycle. While PROG is held Low, the FPGA will drive INIT Low and continue to clear the configuration memory. When PROG is transitioned High, the FPGA finishes the current clear cycle and executes another complete clear cycle, before it goes into a WAIT state and releases INIT. For more information on configuration specifications and timing refer to The Programmable Logic Data Book.

READBACK

Initiating a Readback causes the configuration memory to become accessible to be serially clocked out and read from the device, or byte-wide in the case of SelectMAP/Slave Parallel. The configuration memory contains the configuration data, allowing for a Read-Verification of the configuration data, and can also contain the logic states of the CLB outputs allowing for a Read-Capture of the current design's internal logic states. The Read-Verification and Read-Capture are used by the Hardware Debugger for Hardware Verification. For information on the Readback specification and timing refer to The Programmable Logic Data Book. For information on using the Readback component in a design refer to the Libraries Guide. For information on enabling the Readback function in the Implementation Software refer to the Development System Reference Guide. For information on using the Hardware Debugger refer to the Hardware Debugger Reference/User Guide. For information on connecting the XChecker Cable for Readback refer to the Hardware Users Guide.

STARTUP

The Startup sequence completes a configuration cycle by releasing the DONE Pin, activating the I/O, and de-asserting the Global-Set-Reset (GSR) which globally initializes all internal flip-flops. The sequence of these three steps are user-programmable during bit-stream generation. In order for the FPGA configuration cycle to enter the Startup sequence two conditions must be met: Firstly, the configuration memory must be FULL, and secondly, LengthCount Match must be achieved --in that order. For more information on the Startup sequence and FPGA configuration refer to The Programmable Logic Data Book.

WRITE Pin

The WRITE Pin is an input to a Virtex/Spartan-II during SelectMAP/Slave Parallel mode. It tells the device, which direction the data is flowing on the Data bus. When WRITE is asserted (low), data will be going into the device, which is the case for configuration. When WRITE is de-asserted (high), data will be coming out of the device, which is the case for READBACK. When WRITE is asserted or de-asserted, when the device doesn't expect it, an ABORT occurs. For more information on the WRITE pin, refer to The Programmable Logic Data Book and Application Note 138.

XChecker Cable

The Xilinx XChecker Cable (model DLC4) is a serial download cable. The XChecker uses a serial 9-pin interface to the com port of a host computer and two 8-pin headers for flying-wire connectors to a target board. The XChecker is supported by the Hardware Debugger software for performing Slave Serial configuration and Readback of FPGAs. The XChecker is also supported by the JTAG Programmer software for performing Slave Serial and Boundary Scan configuration of FPGAs, and Boundary Scan programming of CPLDs. For more information on using the XChecker cable refer to the Hardware Users Guide and the Hardware Debugger Reference/Users Guide.


 
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