PE9702 Datasheet, PDF(9/14 Page) Peregrine Semiconductor Corp. – 3.0 GHz Integer-N PLL for Rad Hard Applications

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PE9702 Datasheet, PDF (9/14 Pages) Peregrine Semiconductor Corp. – 3.0 GHz Integer-N PLL for Rad Hard Applications

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PE9702

Advance Information

Main Counter Chain

Normal Operating Mode

The main counter chain divides the RF input

frequency, Fin, by an integer derived from the user-

defined values in the âMâ and âAâ counters. It is

composed of the 10/11 dual modulus prescaler,

modulus select logic, and 9-bit M counter. Setting

Pre_en âlowâ enables the 10/11 prescaler. Setting

Pre_en âhighâ allows Fin to bypass the prescaler

and powers down the prescaler.

The output from the main counter chain, fp, is

related to the VCO frequency, Fin, by the following

equation:

fp = Fin / [10 x (M + 1) + A]

(1)

where A â¤ M + 1, 1 â¤ M â¤ 511

When the loop is locked, Fin is related to the

reference frequency, fr, by the following equation:

Fin = [10 x (M + 1) + A] x (fr / (R+1))

(2)

where A â¤ M + 1, 1 â¤ M â¤ 511

A consequence of the upper limit on A is that Fin

must be greater than or equal to 90 x (fr / (R+1)) to

obtain contiguous channels. Programming the M

Counter with the minimum value of â1â will result in

a minimum M Counter divide ratio of â2â.

In Direct Interface Mode, main counter inputs M7

and M8 are internally forced low. In this mode, the

M value is limited to 1 â¤ M â¤ 127.

Prescaler Bypass Mode

Setting Pre_en âhighâ allows Fin to bypass and

power down the prescaler. In this mode, the 10/11

prescaler and A register are not active, and the

input VCO frequency is divided by the M counter

directly. The following equation relates Fin to the

reference frequency, fr:

Fin = (M + 1) x (fr / (R+1)) )

(3)

where 1 â¤ M â¤ 511

In Direct Interface Mode, main counter inputs M7

and M8 are internally forced low. In this mode, the

M value is limited to 1 â¤ M â¤ 127.

Reference Counter

The reference counter chain divides the reference

frequency, fr, down to the phase detector

comparison frequency, fc.

The output frequency of the 6-bit R Counter is

related to the reference frequency by the following

equation:

fc = fr / (R + 1)

(4)

where 0 â¤ R â¤ 63

Note that programming R with â0â will pass the

reference frequency, fr, directly to the phase

detector.

In Direct Interface Mode, R Counter inputs R4 and

R5 are internally forced low (â0â). In this mode, the

R value is limited to 0 â¤ R â¤ 15.

Parallel Interface Mode

Parallel Interface Mode is selected by setting the

Bmode input âlowâ and the Smode input âlowâ.

Parallel input data, D[7:0], are latched in a parallel

fashion into one of three 8-bit primary register

sections on the rising edge of M1_WR, M2_WR, or

A_WR per the mapping shown in Table 7 on page

10. The contents of the primary register are

transferred into a secondary register on the rising

edge of Hop_WR according to the timing diagram

shown in Figure 5. Data is transferred to the

counters as shown in Table 7 on page 10.

The secondary register acts as a buffer to allow

rapid changes to the VCO frequency. This double

buffering for âping-pongâ counter control is

programmed via the FSELP input. When FSELP is

âhighâ, the primary register contents set the counter

inputs. When FSELP is âlowâ, the secondary

Parallel input data, D[7:0], are latched into the

enhancement register on the rising edge of E_WR

according to the timing diagram shown in Figure 4.

This data provides control bits as shown in Table 8

on page 10 with bit functionality enabled by

asserting the Enh input âlowâ.

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