Crystal Oscillator PPM Error Analysis and Calculation Method

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Crystal Oscillator PPM Error Analysis and Calculation Method [Copy link]

Crystal oscillator accuracy index: PPM

Crystal oscillator accuracy is usually measured in PPM (Parts Per Million), which describes the frequency stability or deviation of a crystal oscillator. PPM represents the relative error between the actual output frequency and the nominal frequency, and is an important parameter for measuring the frequency accuracy of a crystal oscillator.

How to calculate the frequency difference of the crystal oscillator

The frequency difference reflects the difference between the actual frequency of the crystal oscillator and the nominal frequency. The PPM value of the frequency difference is calculated by the formula as follows:

PPM = (actual frequency nominal frequency) / nominal frequency X 10 ⁶

Interpretation:

- Actual Frequency: The actual operating frequency of the crystal oscillator measured by a frequency meter or other appropriate instrument.

- Nominal Frequency: The standard or nominal frequency specified by the crystal manufacturer in the crystal specification sheet.

Example:

For example, if the nominal frequency of a crystal oscillator is 32.768 kHz and the actual measured frequency is 32.7685 kHz, then the PPM calculation is as follows:

PPM=（32768.5Hz32768Hz）/32768Hz*106≈15.26

Frequency difference type: normal temperature frequency difference VS temperature frequency difference

(Graph)

The frequency stability of a crystal oscillator will vary under different temperature conditions. For a crystal oscillator, its frequency accuracy generally includes two important indicators: the frequency difference at room temperature and the frequency difference over temperature:

1. Frequency Tolerance at Normal Temperature: Also called frequency deviation in the YXC specification (see the figure below), it is the deviation from the nominal frequency at normal temperature (25°C), usually expressed in parts per million (PPM).

2. Frequency Versus Temperature Characteristics: It is also called frequency-temperature characteristics in the YXC specification (see the figure below). It refers to the maximum deviation of the actual frequency relative to the nominal frequency within the set operating temperature range, also expressed in parts per million (PPM).

· RTC crystal oscillator 32.768KHz frequency accuracy PPM value and time deviation calculation
For 32.768kHz RTC clock crystal oscillator, the daily time error range can be derived from its frequency accuracy (PPM). The specific steps are as follows:
For example: If the crystal oscillator 32.768KHz accuracy is ±10PPM, the daily time error calculation formula is as follows:
10(PPM)×24(1 day=24 hours)×60(1 hour=60 minutes)×60(1 minute=60 seconds)=864000*1/1000000=0.864 seconds
That is: the daily time error of the RTC crystal oscillator does not exceed 0.864 seconds, that is: if it is +10PPM, it is at most 0.864 seconds faster per day, and if it is -10PPM, it is at most 0.864 seconds slower per day.

(32.768KHz crystal resonator typical application circuit)

RTC clock crystal oscillator 32.768kHz daily time error reference table:

I) ±10PPM: The actual frequency range is 32768.32768Hz~32767.67232Hz, the daily time error is 0.864×1=0.864 seconds, the monthly error is 25.92 seconds, and the total deviation for one year is 5.184 minutes.

lI) ±20PPM: The actual frequency range is 32768.65536Hz~32767.34464Hz, the daily time error is 0.864×2=1.728 seconds, the monthly error is 51.84 seconds, and the total deviation in one year is 10.368 minutes.

lII) ±30PPM: The actual frequency range is 32768.98304Hz~32767.01696Hz, the daily time error is 0.864×3=2.592 seconds, the monthly error is 77.76 seconds, and the total deviation in one year is 15.552 minutes.

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