XC3S400-4FT256C Xilinx Inc, XC3S400-4FT256C Datasheet - Page 37

XC3S400-4FT256C

Manufacturer Part Number

XC3S400-4FT256C

Description

SEMI CONDUCTOR

Manufacturer

Xilinx Inc

Datasheet

1.XC3S400-4FT256C.pdf (208 pages)

Specifications of XC3S400-4FT256C

Case

BGA

04+

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Digital Frequency Synthesizer (DFS)

The DFS component generates clock signals the frequency

of which is a product of the clock frequency at the CLKIN

input and a ratio of two user-determined integers. Because

of the wide range of possible output frequencies such a

ratio permits, the DFS feature provides still further flexibility

than the DLL’s basic synthesis options as described in the

preceding section. The DFS component’s two dedicated

outputs, CLKFX and CLKFX180, are defined in

The signal at the CLKFX180 output is essentially an inver-

sion of the CLKFX signal. These two outputs always exhibit

a 50% duty cycle. This is true even when the CLKIN signal

does not. These DFS clock outputs are driven at the same

time as the DLL’s seven clock outputs.

The numerator of the ratio is the integer value assigned to

the attribute CLKFX_MULTIPLY and the denominator is the

integer value assigned to the attribute CLKFX_DIVIDE.

These attributes are described in

The output frequency (f

tion of the incoming clock frequency (f

Regarding the two attributes, it is possible to assign any

combination of integer values, provided that two conditions

are met:

1. The two values fall within their corresponding ranges,

2. The f

For example, if CLKFX_MULTIPLY = 5 and CLKFX_DIVIDE

= 3, then the frequency of the output clock signal would be

5/3 that of the input clock signal.

DFS Frequency Modes

The DFS supports two operating modes, High Frequency

and Low Frequency, with each specified over a different

clock frequency range. The DFS_FREQUENCY_MODE

attribute chooses between the two modes. When the

attribute is set to LOW, the Low Frequency mode permits

Table 17: DFS Attributes

Table 18: DFS Signals

DS099-2 (v2.2) May 25, 2007

Product Specification

DFS_FREQUENCY_MODE

CLKFX_MULTIPLY

CLKFX_DIVIDE

CLKFX

CLKFX180

CLKFX

Signal

as specified in

expression accords with the DCM’s operating

frequency specifications.

= f

CLKFX

CLKIN

Attribute

Direction

frequency calculated from the above

*(CLKFX_MULTIPLY/CLKFX_DIVIDE) (3)

Output

Table

CLKFX

17.

Multiplies the CLKIN frequency by the attribute-value ratio

(CLKFX_MULTIPLY/CLKFX_DIVIDE) to generate a clock signal with a new target frequency.

Generates a clock signal with same frequency as CLKFX, only shifted 180° out-of-phase.

) can be expressed as a func-

Chooses between High Frequency and Low Frequency modes

Frequency multiplier constant

Frequency divisor constant

Table

CLKIN

17.

) as follows:

Table

www.xilinx.com

18.

Description

the two DFS outputs to operate over a low-to-moderate fre-

quency range. When the attribute is set to HIGH, the High

Frequency mode allows both these outputs to operate at the

highest possible frequencies.

DFS With or Without the DLL

The DFS component can be used with or without the DLL

component:

Without the DLL, the DFS component multiplies or divides

the CLKIN signal frequency according to the respective

CLKFX_MULTIPLY and CLKFX_DIVIDE values, generating

a clock with the new target frequency on the CLKFX and

CLKFX180 outputs. Though classified as belonging to the

DLL component, the CLKIN input is shared with the DFS

component. This case does not employ feedback loop;

therefore, it cannot correct for clock distribution delay.

With the DLL, the DFS operates as described in the preced-

ing case, only with the additional benefit of eliminating the

clock distribution delay. In this case, a feedback loop from

the CLK0 output to the CLKFB input must be present.

The DLL and DFS components work together to achieve

this phase correction as follows: Given values for the

CLKFX_MULTIPLY and CLKFX_DIVIDE attributes, the DLL

selects the delay element for which the output clock edge

coincides with the input clock edge whenever mathemati-

cally possible. For example, when CLKFX_MULTIPLY = 5

and CLKFX_DIVIDE = 3, the input and output clock edges

will coincide every three input periods, which is equivalent

in time to five output periods.

Smaller CLKFX_MULTIPLY and CLKFX_DIVIDE values

achieve faster lock times. With no factors common to the

two attributes, alignment will occur once with every number

of cycles equal to the CLKFX_DIVIDE value. Therefore, it is

recommended that the user reduce these values by factor-

ing

CLKFX_MULTIPLY = 9 and CLKFX_DIVIDE = 6, removing

a factor of three yields CLKFX_MULTIPLY = 3 and

CLKFX_DIVIDE = 2. While both value-pairs will result in the

multiplication of clock frequency by 3/2, the latter value-pair

will enable the DLL to lock more quickly.

Description

wherever

Spartan-3 FPGA Family: Functional Description

possible.

For

Low, High

Integer from 2 to 32

Integer from 1 to 32

example,

Values

given

XC3S400-4FT256C Xilinx Inc, XC3S400-4FT256C Datasheet - Page 37

XC3S400-4FT256C

Specifications of XC3S400-4FT256C

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