XC18V512VQ44I Datasheet XC18V01PC20I, XC18V01SO20I, XC18V01VQ44I | P7-P9

XC18V00 Series In-System Programmable Configuration PROMs

DS026 (v4.1) December 15, 2003 www.xilinx.com 7

Product Specification 1-800-255-7778

The read security bit can be set by the user to prevent the

internal programming pattern from being read or copied via

JTAG. When set, it allows device erase. Erasing the entire

device is the only way to reset the read security bit.

Table 3: Data Security Options

IEEE 1149.1 Boundary-Scan (JTAG)

The XC18V00 family is fully compliant with the IEEE Std.

1149.1 Boundary-Scan, also known as JTAG. A Test

Access Port (TAP) and registers are provided to support all

required boundary scan instructions, as well as many of the

optional instructions specified by IEEE Std. 1149.1. In addi-

tion, the JTAG interface is used to implement in-system pro-

gramming (ISP) to facilitate configuration, erasure, and

verification operations on the XC18V00 device.

Table 4 lists the required and optional boundary-scan

instructions supported in the XC18V00. Refer to the IEEE

Std. 1149.1 specification for a complete description of

boundary-scan architecture and the required and optional

instructions.

Instruction Register

The Instruction Register (IR) for the XC18V00 is eight bits

wide and is connected between TDI and TDO during an

instruction scan sequence. In preparation for an instruction

scan sequence, the instruction register is parallel loaded

with a fixed instruction capture pattern. This pattern is

shifted out onto TDO (LSB first), while an instruction is

shifted into the instruction register from TDI. The detailed

composition of the instruction capture pattern is illustrated

in Figure 3.

The ISP Status field, IR(4), contains logic “1” if the device is

currently in ISP mode; otherwise, it contains logic “0”. The

Security field, IR(3), contains logic “1” if the device has been

programmed with the security option turned on; otherwise, it

contains logic “0”.

Boundary Scan Register

The boundary-scan register is used to control and observe

the state of the device pins during the EXTEST, SAM-

PLE/PRELOAD, and CLAMP instructions. Each output pin

on the XC18V00 has two register stages that contribute to

the boundary-scan register, while each input pin only has

one register stage.

For each output pin, the register stage nearest to TDI con-

trols and observes the output state, and the second stage

closest to TDO controls and observes the High-Z enable

state of the pin.

For each input pin, the register stage controls and observes

the input state of the pin.

Identification Registers

The IDCODE is a fixed, vendor-assigned value that is used

to electrically identify the manufacturer and type of the

device being addressed. The IDCODE register is 32 bits

wide. The IDCODE register can be shifted out for examina-

tion by using the IDCODE instruction. The IDCODE is avail-

able to any other system component via JTAG.

The IDCODE register has the following binary format:

vvvv:ffff:ffff:aaaa:aaaa:cccc:cccc:ccc1

where

v = the die version number

f = the family code (50h for XC18V00 family)

a = the ISP PROM product ID (36h for the XC18V04)

c = the company code (49h for Xilinx)

Note: The LSB of the IDCODE register is always read as

logic “1” as defined by IEEE Std. 1149.1.

Default = Reset Set

Read Allowed

Program/Erase Allowed

Verify Allowed

Read Inhibited via JTAG

Program/Erase Allowed

Verify Inhibited

Table 4: Boundary Scan Instructions

Boundary-Scan

Command

Binary

Code [7:0] Description

Required Instructions

BYPASS 11111111 Enables BYPASS

SAMPLE/

PRELOAD

00000001 Enables boundary-scan

SAMPLE/PRELOAD operation

EXTEST 00000000 Enables boundary-scan

EXTEST operation

Optional Instructions

CLAMP 11111010 Enables boundary-scan

CLAMP operation

HIGHZ 11111100 all outputs in high-impedance

state simultaneously

IDCODE 11111110 Enables shifting out

32-bit IDCODE

USERCODE 11111101 Enables shifting out

32-bit USERCODE

XC18V00 Specific Instructions

CONFIG 11101110 Initiates FPGA configuration

by pulsing CF

pin Low once

IR[7:5] IR[4] IR[3] IR[2] IR[1:0]

TDI-> 0 0 0 ISP

Status

Security 0 0 1 ->TDO

Notes:

1. IR(1:0) = 01 is specified by IEEE Std. 1149.1

Figure 3: Instruction Register Values Loaded into IR as

Part of an Instruction Scan Sequence

XC18V00 Series In-System Programmable Configuration PROMs

8 www.xilinx.com DS026 (v4.1) December 15, 2003

1-800-255-7778 Product Specification

Table 5 lists the IDCODE register values for the XC18V00

devices.

The USERCODE instruction gives access to a 32-bit user

programmable scratch pad typically used to supply informa-

tion about the device’s programmed contents. By using the

USERCODE instruction, a user-programmable identifica-

tion code can be shifted out for examination. This code is

loaded into the USERCODE register during programming of

the XC18V00 device. If the device is blank or was not

loaded during programming, the USERCODE register con-

tains FFFFFFFFh.

XC18V00 TAP Characteristics

The XC18V00 family performs both in-system programming

and IEEE 1149.1 boundary-scan (JTAG) testing via a single

4-wire Test Access Port (TAP). This simplifies system

designs and allows standard Automatic Test Equipment to

perform both functions. The AC characteristics of the

XC18V00 TAP are described as follows.

TAP Timing

Figure 4 shows the timing relationships of the TAP signals.

These TAP timing characteristics are identical for both

boundary-scan and ISP operations.

TAP AC Parameters

Table 6 shows the timing parameters for the TAP waveforms shown in Figure 4.

Table 5: IDCODES Assigned to XC18V00 Devices

ISP-PROM IDCODE

XC18V01 05024093h or 05034093h

XC18V02 05025093h or 05035093h

XC18V04 05026093h or 05036093h

XC18V512 05023093h or 05033093h

Figure 4: Test Access Port Timing

Table 6: Test Access Port Timing Parameters

Symbol Parameter Min Max Units

CKMIN1

TCK minimum clock period 100 - ns

CKMIN2

TCK minimum clock period, Bypass Mode 50 - ns

MSS

TMS setup time 10 - ns

MSH

TMS hold time 25 - ns

DIS

TDI setup time 10 - ns

DIH

TDI hold time 25 - ns

DOV

TDO valid delay - 25 ns

TCK

CKMIN1,2

MSS

TMS

TDI

TDO

MSH

DIH

DOV

DIS

DS026_04_03270

XC18V00 Series In-System Programmable Configuration PROMs

DS026 (v4.1) December 15, 2003 www.xilinx.com 9

Product Specification 1-800-255-7778

Connecting Configuration PROMs

Connecting the FPGA device with the configuration PROM

(see Figure 5 and Figure 6).

• The DATA output(s) of the PROM(s) drives the D

input of the lead FPGA device.

• The Master FPGA CCLK output drives the CLK input(s)

of the PROM(s) (in Master-Serial and

Master-SelectMAP modes only).

• The CEO

output of a PROM drives the CE input of the

next PROM in a daisy chain (if any).

• The OE/RESET

pins of all PROMs are connected to

the INIT

pins of all FPGA devices. This connection

assures that the PROM address counter is reset before

the start of any (re)configuration, even when a

reconfiguration is initiated by a V

CCINT

glitch.

• The PROM CE

input can be driven from the DONE pin.

The CE

input of the first (or only) PROM can be driven

by the DONE output of all target FPGA devices,

provided that DONE is not permanently grounded. CE

can also be permanently tied Low, but this keeps the

DATA output active and causes an unnecessary supply

current of 10 mA maximum.

• Slave-Parallel/SelectMap mode is similar to slave serial

mode. The DATA is clocked out of the PROM one byte

per CCLK instead of one bit per CCLK cycle. See FPGA

data sheets for special configuration requirements.

Initiating FPGA Configuration

The XC18V00 devices incorporate a pin named CF that is

controllable through the JTAG CONFIG instruction. Execut-

ing the CONFIG instruction through JTAG pulses the CF

low once for 300-500 ns, which resets the FPGA and ini-

tiates configuration.

The CF

pin must be connected to the PROGRAM pin on the

FPGA(s) to use this feature.

The iMPACT software can also issue a JTAG CONFIG

command to initiate FPGA configuration through the “Load

FPGA” setting.

The 20-pin packages do not have a dedicated CF

pin. For

20-pin packages, the CF --> D4 setting can be used to route

the CF

pin function to pin 7 only if the parallel output mode

is not used.

Selecting Configuration Modes

The XC18V00 accommodates serial and parallel methods

of configuration. The configuration modes are selectable

through a user control register in the XC18V00 device. This

control register is accessible through JTAG, and is set using

the “Parallel mode” setting on the Xilinx iMPACT software.

Serial output is the default configuration mode.

Master Serial Mode Summary

The I/O and logic functions of the Configurable Logic Block

(CLB) and their associated interconnections are estab-

lished by a configuration program. The program is loaded

either automatically upon power up, or on command,

depending on the state of the three FPGA mode pins. In

Master Serial mode, the FPGA automatically loads the con-

figuration program from an external memory. Xilinx PROMs

are designed to accommodate the Master Serial mode.

Upon power-up or reconfiguration, an FPGA enters the Mas-

ter Serial mode whenever all three of the FPGA mode-select

pins are Low (M0=0, M1=0, M2=0). Data is read from the

PROM sequentially on a single data line. Synchronization is

provided by the rising edge of the temporary signal CCLK,

which is generated by the FPGA during configuration.

Master Serial Mode provides a simple configuration inter-

face. Only a serial data line, a clock line, and two control

lines are required to configure an FPGA. Data from the

PROM is read sequentially, accessed via the internal

address and bit counters which are incremented on every

valid rising edge of CCLK. If the user-programmable,

dual-function D

pin on the FPGA is used only for configu-

ration, it must still be held at a defined level during normal

operation. The Xilinx FPGA families take care of this auto-

matically with an on-chip pull-up resistor.

Cascading Configuration PROMs

For multiple FPGAs configured as a serial daisy-chain, or a

single FPGA requiring larger configuration memories in a

serial or SelectMAP configuration mode, cascaded PROMs

provide additional memory (Figure 5). Multiple XC18V00

devices can be concatenated by using the CEO

output to

drive the CE

input of the downstream device. The clock

inputs and the data outputs of all XC18V00 devices in the

chain are interconnected. After the last data from the first

PROM is read, the next clock signal to the PROM asserts its

CEO

output Low and drives its DATA line to a high-imped-

ance state. The second PROM recognizes the Low level on

its CE

input and enables its DATA output. See Figure 7.

After configuration is complete, address counters of all cas-

caded PROMs are reset if the PROM OE/RESET

pin goes

Low or CE

goes High.

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