What question did this study set out to answer?

The aim is to analyze and optimize frequency offset errors in deep-space UXB tracking systems.

April 1, 2026Open Access

Frequency Error Analysis and Optimization in UXB Satellite TT&C Systems

Key Points

The aim is to analyze and optimize frequency offset errors in deep-space UXB tracking systems.
Analyzing phase-locked loop (PLL) performance and digital processing of UXB systems.
Developing a digital system model incorporating FFT-based coarse acquisition.
Utilizing a digital Costas loop for carrier synchronization.
Conducting simulations with varying quantization levels (32-bit vs. 48-bit).
32-bit quantization resulted in unacceptable frequency offset errors.
Extending quantization to 48 bits reduced frequency offset error by approximately 216 times.
Achieved velocity accuracy of sub-0.01 mm/s, significantly improving measurement coherence.

Abstract

High-precision Doppler measurement is essential for deep-space Unified X-band (UXB) tracking systems, yet digital implementations suffer from finite word-length quantization errors that degrade performance. This study analyzes frequency offset errors in UXB transponder systems, focusing on the phase-locked loop (PLL) and system-level digital processing. A digital system model is presented, featuring an FFT-based coarse acquisition and a digital Costas loop for carrier synchronization. The simulation results reveal that 32-bit quantization yields unacceptable frequency offset errors. By extending critical paths to 48 bits, the system reduces frequency offset error by approximately 216 and achieves sub-0.01 mm/s velocity accuracy, significantly improving coherence and meeting deep-space measurement requirements.

Frequency Error Analysis and Optimization in UXB Satellite TT&C Systems

Key Points

Abstract

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