ADF4157BRUZ-RL Analog Devices Inc, ADF4157BRUZ-RL Datasheet - Page 19

ADF4157BRUZ-RL

Manufacturer Part Number

ADF4157BRUZ-RL

Description

IC,FREQUENCY SYNTHESIZER,CMOS,TSSOP,16PIN,PLASTIC

Manufacturer

Analog Devices Inc

Type

Fractional N Synthesizer (RF)r

Datasheet

1.ADF4157BRUZ.pdf (24 pages)

Specifications of ADF4157BRUZ-RL

Pll

Yes

Input

CMOS

Output

Clock

Number Of Circuits

Ratio - Input:output

2:1

Differential - Input:output

Yes/No

Frequency - Max

6GHz

Divider/multiplier

Yes/Yes

Voltage - Supply

2.7 V ~ 3.3 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

16-TSSOP

Frequency-max

6GHz

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

For Use With

EVAL-ADF4157EB1Z - BOARD EVALUATION FOR ADF4157

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Current page: 19 of 24
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FASTLOCK TIMER AND REGISTER SEQUENCES

If the fastlock mode is used, a timer value needs to be loaded into

the PLL to determine the time spent in wide bandwidth mode.

When Bits DB[20:19] in Register 4 (R4) are set to 01 (switched

R fastlock enable), the timer value is loaded via the 12-bit clock

divider value. To use fastlock, the PLL must be written to in the

following sequence:

FASTLOCK: AN EXAMPLE

If a PLL has f

the PLL is set to wide bandwidth for 40 μs.

If the time period set for the wide bandwidth is 40 μs, then

Therefore, 520 must be loaded into the clock divider value in

Fastlock Timer and Register Sequences section.

FASTLOCK: LOOP FILTER TOPOLOGY

To use fastlock mode, an extra connection from the PLL to the

loop filter is needed. The damping resistor in the loop filter must

be reduced to ¼ of its value while in wide bandwidth mode. This is

required because the charge pump current is increased by 16

while in wide bandwidth mode, and stability must be ensured.

During fastlock, the MUXOUT pin (after setting MUXOUT to

fastlock switch by setting Bits DB[30:27] in Register 0 to 1100) is

shorted to ground (this is accomplished by settings Bits DB[20:19]

in Register 4 to 01—switched R fastlock enable). The following

two topologies can be used:

•

Use the initialization sequence (see the Initialization

Sequence section) only once after powering up the part.

Load Register 4 (R4) with Bits DB[20:19] set to 01 and the

chosen fastlock timer value (DB18 to DB7). Note that the

duration that the PLL remains in wide bandwidth is equal

to the fastlock timer/f

Fastlock Timer Value = Time in Wide Bandwidth × f

Fastlock Timer Value = 40 μs × 13 MHz = 520

Divide the damping resistor (R1) into two values (R1 and

R1A) that have a ratio of 1:3 (see Figure 22).

Connect an extra resistor (R1A) directly from MUXOUT,

as shown in Figure 23. The extra resistor must be chosen

such that the parallel combination of an extra resistor and

the damping resistor (R1) is reduced to ¼ of the original

value of R1 (see Figure 23).

Figure 22. Fast ock Loop Filter Topology—Topology 1

ADF4157

PFD

MUXOUT

= 13 MHz and a required lock time of 50 μs,

PFD

R1A

VCO

PFD

Rev. A | Page 19 of 24

SPUR MECHANISMS

The fractional interpolator in the ADF4157 is a third-order Σ-Δ

modulator (SDM) with a 25-bit fixed modulus (MOD). The

SDM is clocked at the PFD reference rate (f

output frequencies to be synthesized at a channel step resolution of

N synthesizers, and how they affect the ADF4157, are discussed in

this section.

Fractional Spurs

In most fractional synthesizers, fractional spurs can appear at

the set channel spacing of the synthesizer. In the ADF4157,

these spurs do not appear. The high value of the fixed modulus

in the ADF4157 makes the Σ-Δ modulator quantization error

spectrum look like broadband noise, effectively spreading the

fractional spurs into noise.

Integer Boundary Spurs

Interactions between the RF VCO frequency and the PFD fre-

quency can lead to spurs known as integer boundary spurs. When

these frequencies are not integer related (which is the purpose

of the fractional-N synthesizer), spur sidebands appear on the

VCO output spectrum at an offset frequency that corresponds

to the beat note or difference frequency between an integer mul-

tiple of the PFD and the VCO frequency.

These spurs are named integer boundary spurs because they are

more noticeable on channels close to integer multiples of the PFD

where the difference frequency can be inside the loop bandwidth.

These spurs are attenuated by the loop filter.

Figure 7 shows an integer boundary spur. The RF frequency is

5800.25 MHz, and the PFD frequency is 25 MHz. The integer

boundary spur is 250 kHz from the carrier at an integer times

the PFD frequency (232 × 25 MHz = 5800 MHz). The spur also

appears on the upper sideband.

Reference Spurs

Reference spurs are generally not a problem in fractional-N

synthesizers because the reference offset is far outside the loop

bandwidth. However, any reference feedthrough mechanism

that bypasses the loop can cause a problem. One such mechanism

is the feedthrough of low levels of on-chip reference switching

noise out through the RF

reference spur levels as high as −90 dBc. Care should be taken in

the PCB layout to ensure that the VCO is well separated from

PFD

/MOD. The various spur mechanisms possible with fractional-

Figure 23. Fastlock Loop Filter Topology—Topology 2

ADF4157

MUXOUT

R1A

x pin back to the VCO, resulting in

PFD

) that allows PLL

ADF4157

VCO

ADF4157BRUZ-RL Analog Devices Inc, ADF4157BRUZ-RL Datasheet - Page 19

ADF4157BRUZ-RL

Specifications of ADF4157BRUZ-RL

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