AD9517-4/PCBZ Analog Devices Inc, AD9517-4/PCBZ Datasheet - Page 43

AD9517-4/PCBZ

Manufacturer Part Number

AD9517-4/PCBZ

Description

BOARD EVALUATION AD9517-4

Manufacturer

Analog Devices Inc

Datasheet

1.AD9517-4ABCPZ-RL7.pdf (80 pages)

Specifications of AD9517-4/PCBZ

Design Resources

High Performance, Dual Channel IF Sampling Receiver (CN0140)

Main Purpose

Timing, Clock Generator

Utilized Ic / Part

AD9517-4

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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Divider

Phase Offset or Coarse Time Delay (0, 1)

Each channel divider allows for a phase offset, or a coarse time

delay, to be programmed by setting register bits (see Table 38).

These settings determine the number of cycles (successive

rising edges) of the channel divider input frequency by which to

offset, or delay, the rising edge of the output of the divider. This

delay is with respect to a nondelayed output (that is, with a

phase offset of zero). The amount of the delay is set by five bits

loaded into the phase offset (PO) register plus the start high (SH)

bit for each channel divider. When the start high bit is set, the

delay is also affected by the number of low cycles (M)

programmed for the divider.

The SYNC function must be used to make phase offsets effective

(see the Synchronizing the Outputs—SYNC Function section).

Table 38. Setting Phase Offset and Division for Divider 0 and

Divider 1

Let

Δt = delay (in seconds).

Δc = delay (in cycles of clock signal at input to D

(in seconds).

Φ = 16 × SH[4] + 8 × PO[3] + 4 × PO[2] + 2 × PO[1] + 1 × PO[0]

The channel divide-by is set as N = high cycles and M = low cycles.

Case 1

For Φ ≤ 15:

Δt = Φ × T

Δc = Δt/T

Case 2

For Φ ≥ 16:

Δt = (Φ − 16 + M + 1) × T

Δc = Δt/T

By giving each divider a different phase offset, output-to-output

delays can be set in increments of the channel divider input

clock cycle. Figure 54 shows the results of setting such a coarse

offset between outputs.

DIVIDER 0

DIVIDER 1

DIVIDER 2

= period of the clock signal at the input of the divider, D

DIVIDER INPUT

CHANNEL

SH = 0

PO = 0

SH = 0

PO = 1

SH = 0

PO = 2

Start

High (SH)

0x191[4]

0x197[4]

= Φ

Figure 54. Effect of Coarse Phase Offset (or Delay)

Phase

Offset (PO)

0x191[3:0]

0x197[3:0]

1 × Tx

2 × Tx

Low Cycles

0x190[7:4]

0x196[7:4]

9 10 11 12 13 14 15

High Cycles

0x190[3:0]

0x196[3:0]

Rev. B | Page 43 of 80

Channel Dividers—LVDS/CMOS Outputs

Channel Divider 2 and Channel Divider 3 each drive a pair of

LVDS outputs, giving four LVDS outputs (OUT4 to OUT7).

Alternatively, each of these LVDS differential outputs can be

configured individually as a pair (A and B) of CMOS single-

ended outputs, providing for up to eight CMOS outputs. By

default, the B output of each pair is off but can be turned on as

desired.

Channel Divider 2 and Channel Divider 3 each consist of two

cascaded, 2 to 32, frequency dividers. The channel frequency

division is D

bypassing one or both of these dividers. Both of the dividers

also have DCC enabled by default, but this function can be

disabled, if desired, by setting the DCCOFF bit of the channel.

A coarse phase offset or delay is also programmable (see the

Phase Offset or Coarse Time Delay (Divider 2 and Divider 3)

section). The channel dividers operate up to 1600 MHz. The

features and settings of the dividers are selected by programming

the appropriate setup and control registers (see Table 52 and

Table 53 through Table 62).

Table 39. Setting Division (D

Divider

Channel Frequency Division (Divider 2 and Divider 3)

The division for each channel divider is set by the bits in the

registers for the individual dividers (X.Y = 2.1, 2.2, 3.1, and 3.2)

When both X.1 and X.2 are bypassed, D

When only X.2 is bypassed, D

When both X.1 and X.2 are not bypassed, D

By cascading the dividers, channel division up to 1024 can be

obtained. However, not all integer value divisions from 1 to

1024 are obtainable; only the values that are the product of the

separate divisions of the two dividers (D

If only one divider is needed when using Divider 2 and Divider 3,

use the first one (X.1) and bypass the second one (X.2). Do not

bypass X.1 and use X.2.

Note that the value stored in the register = # of cycles minus 1.

X.2

Number of Low Cycles = M

Number of High Cycles = N

2.1

2.2

3.1

3.2

+ M

X.2

0x199[7:4]

0x19B[7:4]

0x19E[7:4]

0x1A0[7:4]

+ 2).

X.1

× D

X.2

or up to 1024. Divide-by-1 is achieved by

0x199[3:0]

0x19B[3:0]

0x19E[3:0]

0x1A0[3:0]

= (N

) for Divider 2, Divider 3

X.Y

+ 1

X.1

+ M

Bypass

0x19C[4]

0x19C[5]

0x1A1[4]

0x1A1[5]

× D

= 1 × 1 = 1.

X.1

= (N

X.2

+ 2) × 1.

) can be realized.

X.1

AD9517-4

+ M

DCCOFF

0x19D[0]

0x1A2[0]

X.1

+ 2) ×

AD9517-4/PCBZ Analog Devices Inc, AD9517-4/PCBZ Datasheet - Page 43

AD9517-4/PCBZ

Specifications of AD9517-4/PCBZ

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