Frequency error due to phase error, Frequency error due to phase error -17, Frequency – INFICON PLO-10i Phase Lock Oscillator User Manual

PLO-10 PHASE LOCK OSCILLATOR

THEORY OF OPERATION

8-17

8.7.2 FREQUENCY ERROR DUE TO PHASE ERROR

Given some finite zero phase error, the resulting frequency error depends on the sensing

crystal’s Q, the higher the Q, the lower the error. For phase errors below 10 degrees the

frequency error is 0.087 PPM per degree for crystals with a Q of 100,000. Thus a one

degree phase error in the PLO results in a 0.44 Hz frequency error for a 5MHz crystal

with a Q of 100,000. For a 5 MHz crystal with a Q of 10,000, the error is 10 time greater

or 4.4 Hz per degree.

Frequency Error/deg = df/f = π/(360*Q)

8.7.3 FREQUENCY ERROR DUE TO IMPERFECT CAPACITANCE CANCELLATION

The effect of imperfect electrode capacitance cancellation can also be viewed as an

equivalent phase error. This error is directly proportional to crystal resistance. The

equivalent phase error due to a non-zero shunt capacitance equal to 1 pfd is one degree

for a crystal with a series resistance of 556 Ω. Since the equivalent phase error is

proportional to the crystal resistance, a 1-pfd residual capacitance error will result in a

10-degree equivalent error for a sensing crystal with a resistance of 5.56 KΩ.

8.8 FREQUENCY ERRORS DUE TO IMPERFECT CAPACITANCE

CANCELLATION

There are two reasons that proper capacitance cancellation is so important with high

resistance crystals.
The first is that to a first approximation, the frequency error resulting from a given phase

error is proportional to the bandwidth of the crystal. The bandwidth of the crystal is

proportional to the crystal’s resistance. A ten-ohm crystal might typically have a

bandwidth of 42 Hz, while a one thousand-ohm crystal will have a bandwidth of 4,200

Hz. A five thousand-ohm crystal will have a bandwidth of 21,000 Hz. Since the

frequency error for a given phase error is proportional to the bandwidth, a phase error that

would result in a 0.5 Hz frequency error in a ten ohm crystal will cause a 50 Hz error in a

one thousand ohm crystal and 250 Hz error in a five thousand ohm crystal.
The second reason is that the effective phase error caused by a non-zero net quadrature

current is inversely proportional to the real current, which is inversely proportional to the

crystal resistance. In other words, the effective phase error is proportional to the crystal

resistance. For instance, a net unbalance of 1 pfd leads to an effective phase error of 0.02

degrees for a ten ohm crystal, but it leads to a 2 degree error for a one thousand ohm

crystal and a 10 degree error for a five thousand ohm crystal.

Examples:
A ten-ohm, 5 MHz crystal will have a Q (Quality Factor) of about 120,000. The

bandwidth is equal to the crystal frequency divided by Q. Thus, the bandwidth of this

crystal would be about 42 Hz. To a first approximation, near zero phase, the frequency

error per degree of phase error is given by the following formula,

Frequency Error = -½(Phase Error, in radians)(Bandwidth)