Starting from the physical heartbeat of the crystal oscillator, it eventually reaches the acoustic frontier with femtosecond-level precision.
This is not merely a list of technical parameters, nor is it merely the establishment of different clock optimization schemes for various scenarios. Rather, it is a cognitive revolution about "how time shapes sound".
The precise playback of digital audio cannot be achieved without an invisible commander - the audio clock.
It is like the metronome in a symphony orchestra, ensuring that each note is played at the correct time.
A 44.1kHz sampling rate means capturing 44,100 sound snapshots per second, and the accuracy of the clock determines whether these snapshots are evenly arranged.
First Layer: Basic Understanding?
The clock error of a common crystal oscillator can reach ±100 ppm (typical value for temperature frequency difference). When playing music for 3 minutes, the theoretical maximum time deviation is approximately 0.018 seconds – equivalent to the drummer in a 120 BPM piece being ahead by 1/28 beats compared to the lead singer.
Professional audio equipment uses TCXO (temperature-compensated crystal oscillator), which compresses the error to ±0.5 ppm, increasing the timing accuracy by up to 200 times and achieving sub-millisecond synchronization.
Second Layer: Deep Impact?
Clock jitter can cause sampling phase shift, resulting in sound distortion and harmonic distortion.
The human ear is sensitive to jitter at the microsecond level (capable of perceiving the discontinuity in piano sustain).
Compressing the jitter to the picosecond level is equivalent to having an error of less than 0.5 millimeters (approximately equal to 5 strands of hair) in a 100-meter race. Femtosecond-level jitter (such as in OCXO technology) can achieve atomic-scale precision (an error of less than 0.01 nanometers in a 100-meter race).
The clock is like the quantum-scale heartbeat of digital audio. With each precise beat, it eliminates the erosion of time-base errors (clock jitter/phase noise) on the sound field, restoring the true boundaries of hearing.
尺寸 | 頻率 | 精度 | 應用場景 |
DIP14/3225/2520 | 49.152 MHz | ±10PPM | audio |
24.576 MHz | ±10PPM | audio | |
45.1584 MHz | ±10PPM | audio | |
22.5792 MHz | ±10PPM | audio | |
11.2896 MHz | ±10PPM | audio | |
12.288 MHz | ±10PPM | audio |
SCTF Star Communication Time-Frequency Application Professional Audio Clock Selection
