GS7025 Datasheet, PDF(10/13 Page) Gennum Corporation

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GS7025 Datasheet, PDF (10/13 Pages) Gennum Corporation – Serial Digital Receiver

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3. FREQUENCY ACQUISITION

The core PLL is able to lock if the incoming data rate and

the PLL clock frequency are within the PLL capture range

(which is slightly larger than the loop bandwidth). To assist

the PLL to lock, the GS7025 uses a frequency acquisition

circuit.

The frequency acquisition circuit sweeps the VCO control

voltage so that the VCO frequency changes from -10% to

+10% of the centre frequency. Figure 11 shows a typical

sweep waveform.

tswp

tsys

VLF

Tcycle

Tcycle = tswp + tsys

Fig. 11 Typical Sweep Waveform

The VCO frequency starts at point A and sweeps up

attempting to lock. If lock is not established during the up

sweep, the VCO is then swept down. The system is

designed such that the probability of locking within one

cycle period is greater than 0.999. If the system does not

lock within one cycle period, it will attempt to lock in the

subsequent cycle.

The average sweep time, tswp, is determined by the loop

filter component, CLF1, and the charge pump current, ÎCP:

tSWP

4----C-----L---F---1-

3ICP

The nominal sweep time is approximately 121Âµs when

CLF1 = 15nF and ÎCP = 165ÂµA (RVCO = 365â¦).

An internal system clock determines tsys (see section 3-1,

Logic Circuit).

3-1. Logic Circuit

The GS7025 is controlled by a finite state logic circuit which

is clocked by an asynchronous system clock. That is, the

system clock is completely independent of the incoming

data rate. The system clock runs at low frequencies, relative

to the incoming data rate, and thus reduces interference to

the PLL.The period of the system clock is set by the COSC

capacitor and is:

tsys = 9.6 Ã 104 Ã COSC[ sec onds]

The recommended value for tsys is 450Âµs (COSC = 4.7nF)

4. LOCKING

The GS7025 indicates valid lock when the following three

conditions are satisfied:

1. Input data is detected.

2. The incoming data signal and the PLL clock are phase

locked.

3. The system is not locked to an integer-multiple harmonic

of a 270Mb/s SMPTE 259M-C signal.

The GS7025 defines the presence of input data when at

least one data transition occurs every 1Âµs.

The GS7025 assumes that it is NOT locked to a harmonic if

the pattern â101â or â010â (in the reclocked data stream)

occurs at least once every tsys/3 seconds. Using the

recommended component values, this corresponds to

approximately 150Âµs. In a harmonically locked system, all

bit cells are double clocked and the above patterns

become â110011â and â001100â, respectively.

4-1. Lock Time

Synchronous switching refers to the case where the input

data is changed from one source to another source which is

at the same data rate (but different phase).

When input data to the GS7025 is removed, the GS7025

latches the current state. Therefore, when data is reapplied,

the GS7025 begins the lock procedure at the previous

locked data rate. As a result, in synchronous switching

applications, the GS7025 locks very quickly. The nominal

lock time depends on the switching time and is summarized

in the Table 3.

TABLE 3.

SWITCHING TIME

<0.5Âµs

0.5Âµs - 10ms

>10ms

LOCK TIME

10Âµs

2tsys

2Tcycle + 2tsys

To acquire lock, the frequency acquisition circuit may have

to sweep over an entire cycle depending on initial

conditions. Maximum lock time is 2Tcycle + 2tsys.

The nominal value of Tcycle for the GS7025 operating in a

typical SMPTE 259M-C application is approximately 1.3ms.

The GS7025 has a dedicated LOCK output (pin 39)

indicating when the device is locked. It should be noted

that in synchronous switching applications where the

switching time is less than 0.5Âµs, the LOCK output will NOT

be de-asserted and the data outputs will NOT be muted.

GENNUM CORPORATION

522 - 80 - 00

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