DS001 Datasheet, PDF(30/99 Page) Xilinx, Inc

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DS001 Datasheet, PDF (30/99 Pages) Xilinx, Inc – Spartan-II FPGA Family

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Spartan-II FPGA Family: Functional Description

Startup Delay Property

This property, STARTUP_WAIT, takes on a value of TRUE

or FALSE (the default value). When TRUE the Startup

Sequence following device configuration is paused at a

user-specified point until the DLL locks. XAPP176:

Configuration and Readback of the Spartan-II and

Spartan-IIE Families explains how this can result in delaying

the assertion of the DONE pin until the DLL locks.

DLL Location Constraints

The DLLs are distributed such that there is one DLL in each

corner of the device. The location constraint LOC, attached

to the DLL primitive with the numeric identifier 0, 1, 2, or 3,

controls DLL location. The orientation of the four DLLs and

their corresponding clock resources appears in Figure 27.

The LOC property uses the following form.

LOC = DLL2

GCLKPAD3

DLL3

GCLKBUF3

GCLKPAD2

DLL2

GCLKBUF2

GCLKBUF1

DLL1

GCLKPAD1

GCLKBUF0

DLL0

GCLKPAD0

DS001_27_061308

Figure 27: Orientation of DLLs

Design Considerations

Use the following design considerations to avoid pitfalls and

improve success designing with Xilinx devices.

Input Clock

The output clock signal of a DLL, essentially a delayed

version of the input clock signal, reflects any instability on

the input clock in the output waveform. For this reason the

quality of the DLL input clock relates directly to the quality of

the output clock waveforms generated by the DLL. The DLL

input clock requirements are specified in the "DLL Timing

Parameters" section of the data sheet.

In most systems a crystal oscillator generates the system

clock. The DLL can be used with any commercially

available quartz crystal oscillator. For example, most crystal

oscillators produce an output waveform with a frequency

tolerance of 100 PPM, meaning 0.01 percent change in the

clock period. The DLL operates reliably on an input

waveform with a frequency drift of up to 1 ns â orders of

magnitude in excess of that needed to support any crystal

oscillator in the industry. However, the cycle-to-cycle jitter

must be kept to less than 300 ps in the low frequencies and

150 ps for the high frequencies.

Input Clock Changes

Changing the period of the input clock beyond the

maximum drift amount requires a manual reset of the

CLKDLL. Failure to reset the DLL will produce an unreliable

lock signal and output clock.

It is possible to stop the input clock in a way that has little

impact to the DLL. Stopping the clock should be limited to

less than approximately 100 Î¼s to keep device cooling to a

minimum and maintain the validity of the current tap setting.

The clock should be stopped during a Low phase, and when

restored the full High period should be seen. During this

time LOCKED will stay High and remain High when the

clock is restored. If these conditions may not be met in the

design, apply a manual reset to the DLL after re-starting the

input clock, even if the LOCKED signal has not changed.

When the clock is stopped, one to four more clocks will still

be observed as the delay line is flushed. When the clock is

restarted, the output clocks will not be observed for one to

four clocks as the delay line is filled. The most common

case will be two or three clocks.

In a similar manner, a phase shift of the input clock is also

possible. The phase shift will propagate to the output one to

four clocks after the original shift, with no disruption to the

CLKDLL control.

Output Clocks

As mentioned earlier in the DLL pin descriptions, some

restrictions apply regarding the connectivity of the output

pins. The DLL clock outputs can drive an OBUF, a global

clock buffer BUFG, or route directly to destination clock

pins. The only BUFGs that the DLL clock outputs can drive

are the two on the same edge of the device (top or bottom).

One DLL output can drive more than one OBUF; however,

this adds skew.

Do not use the DLL output clock signals until after activation

of the LOCKED signal. Prior to the activation of the

LOCKED signal, the DLL output clocks are not valid and

can exhibit glitches, spikes, or other spurious movement.

DS001-2 (v2.8) June 13, 2008

Product Specification

www.xilinx.com

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