SI4114G-B-GM Silicon Laboratories Inc, SI4114G-B-GM Datasheet - Page 14

SI4114G-B-GM

Manufacturer Part Number

SI4114G-B-GM

Description

IC RF SYNTH FOR GSM/GPRS 28QFN

Manufacturer

Silicon Laboratories Inc

Type

Frequency Synthesizerr

Datasheet

1.SI4114G-BM.pdf (24 pages)

Specifications of SI4114G-B-GM

Pll

Yes

Input

Clock

Output

Clock

Number Of Circuits

Ratio - Input:output

1:1

Differential - Input:output

No/No

Frequency - Max

1.99GHz

Divider/multiplier

Yes/No

Voltage - Supply

2.7 V ~ 2.9 V

Operating Temperature

-20°C ~ 70°C

Mounting Type

Surface Mount

Package / Case

28-QFN

Frequency-max

1.99GHz

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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S i 4 11 4 G

3. Functional Description

The Si4114G is a monolithic integrated circuit (IC) that

performs multi-band RF synthesis for E-GSM 900,

DCS 1800, and PCS 1900 applications. Its fast transient

response also makes the Si4114G especially well suited

to GPRS multislot applications where channel switching

and settling times are critical. This IC, with a minimum

number of external components, is all that is necessary

to implement the frequency synthesis function.

The Si4114G has two complete phase-locked loops

(PLLs) with integrated voltage-controlled oscillators

(VCOs). The low phase noise of the VCOs makes the

Si4114G suitable for use in demanding wireless

communications applications. Also integrated are phase

detectors, loop filters, and reference dividers. The IC is

programmed through a three-wire serial interface.

Two RF PLLs are provided to cover the 1710–

1990 MHz

1990 MHz; RF2 covers 1710–1840 MHz.

The center frequency of each VCO is set by an internal

L-C tank circuit. Inaccuracies in this tank due to

temperature

compensated for by the Si4114G’s proprietary self-

tuning algorithm. This algorithm is initiated each time

the PLL is powered up (by either the PWDN pin or by

software) and/or each time a new output frequency is

programmed.

The unique PLL architecture used in the Si4114G

produces a transient response that is superior in speed

to fractional-N architectures without suffering the high

phase noise or spurious modulation effects often

associated with those designs.

3.1. Serial Interface

A timing diagram for the serial interface is shown in

Figure 2 on page 7. Figure 3 on page 7 shows the

format of the serial word.

The Si4114G is programmed serially with 22-bit words

comprised of 18-bit data fields and 4-bit address fields.

When the serial interface is enabled (i.e., when SEN is

low) data and address bits on the SDATA pin are

clocked into an internal shift register on the rising edge

of SCLK. Data in the shift register is then transferred on

the rising edge of SEN into the internal data register

addressed in the address field. The serial interface is

disabled when SEN is high.

Table 7 on page 17 summarizes the data register

functions and addresses. The internal shift register will

ignore any leading bits before the 22 required bits.

frequency

small

span.

manufacturing

RF1

covers

offsets

1840–

are

Rev. 1.1

3.2. Self-Tuning Algorithm

The self-tuning algorithm is initiated immediately

following powerup of a PLL or, if the PLL is already

powered, following a change in its programmed output

frequency. This algorithm attempts to coarse-tune the

VCO so that its free-running frequency is near the

desired output frequency. In so doing, the algorithm will

compensate for errors in the L-C tank circuit. It will also

reduce the frequency error for which the PLL must

correct to get the precise desired output frequency. The

self-tuning algorithm will leave the VCO oscillating at a

frequency in error by somewhat less than 1% of the

desired output frequency.

After self-tuning, the PLL controls the VCO oscillation

frequency. The PLL will complete frequency locking,

eliminating any remaining frequency error. Thereafter, it

will maintain frequency lock, compensating for effects

caused by temperature and supply voltage variations.

The Si4114G’s self-tuning algorithm will compensate for

component value errors at any temperature within the

specified temperature range. However, the ability of the

PLL to compensate for drift in component values that

occur AFTER self-tuning is limited. The PLL will be able

to maintain lock for changes in temperature of

approximately ±30 °C.

Applications such as GSM handsets where the PLL is

regularly powered down or switched between channels

eliminate the potential effects of temperature drift

because the VCO is re-tuned when it is powered up or

when a new frequency is programmed. In applications

where the ambient temperature can drift substantially

after self-tuning, it may be necessary to monitor the

LDETB (lock-detect bar) signal on the AUXOUT pin to

determine the locking state of the PLL. (See "3.8.

Auxiliary Output (AUXOUT)" on page 15 for how to

select LDETB.)

The LDETB signal is normally low after self-tuning is

completed but will rise when the PLL nears the limit of

its compensation range (LDETB will also be high when

either PLL is executing the self-tuning algorithm). The

output frequency will still be locked when LDETB goes

high, but the PLL will eventually lose lock if the

temperature continues to drift in the same direction.

Therefore, if LDETB goes high the RF PLLs should

promptly be re-tuned by initiating the self-tuning

algorithm.

3.3. Output Frequencies

The RF output frequencies are set by programming the

N-Divider registers. Each RF PLL has its own N register

and can be programmed independently. Programming

the

N-Divider

for

either

RF1

RF2

SI4114G-B-GM Silicon Laboratories Inc, SI4114G-B-GM Datasheet - Page 14

SI4114G-B-GM

Specifications of SI4114G-B-GM

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