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Virtual image inhibiting method and circuit

A technology of virtual image and input signal, applied in the field of signal processing, can solve problems such as the inability to meet the requirements of broadband communication, achieve the effect of being easy to understand, solve long-term problems, and reduce hardware overhead

Inactive Publication Date: 2013-08-07
TIANJING YIRONG TECH
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AI Technical Summary

Problems solved by technology

A frequency-independent virtual image suppression correction algorithm is used to correct the frequency-related two-way mismatch problem. In narrowband communication (such as GSM with a bandwidth of 200kHz), the actual virtual image suppression ratio performance is limited to 60-70dB in a circuit that matches no more than 30dB. In broadband communication (2Mhz WCDMA), the actual virtual image suppression ratio is limited between 50-60dB, while in 6-8M bandwidth TV reception, the correction algorithm can basically only guarantee 45-50dB VIR
Therefore, the frequency-independent virtual image suppression correction algorithm cannot meet the requirements of broadband communication (>70dB)

Method used

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  • Virtual image inhibiting method and circuit

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Embodiment Construction

[0041] Such as Figure 9 As shown, the first output of the processor is connected to a frequency-variable sine generator, and at the same time, the digital signal converted by the analog-to-digital converter from two analog input signals is simultaneously connected to the frequency mixer On the mixer, then the mixer is connected to a digital low-pass filter or a band-pass filter, and then the output of the digital low-pass filter or the band-pass filter is connected to the processor for data processing, and the second output of the processor The terminal is connected to a complex coefficient filter. One end of the input signal is connected to the complex coefficient filter after analog-to-digital conversion, and the output of the complex coefficient filter is used as one of the signal output terminals after virtual image suppression, and the other end of the input signal is directly used as a virtual image suppression signal after analog-to-digital conversion the other side o...

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Abstract

The invention discloses a virtual image inhibiting method. Based on N-1-order finite impact response filter, a frequency-irrelevant virtual image correction algorithm and a coordinate rotating digital computing method are adopted, and the computing capacity of a system on chip is combined to inhibit virtual images of input signals. The method is characterized by comprising the following steps of:selecting N frequency points fi in the frequency band of an input signal, and generating a sinusoidal waveform corresponding to each frequency point fi one by one by adopting the coordinate rotating digital computing method; mixing and filtering the series of sinusoidal waveforms obtained with the input signal one by one, traversing the N frequency points fi, obtaining a set of two mixed paths ofamplitude difference and phase difference, and inputting into the system on chip, solving an equation set that the set is associated with the N-1-order finite impact response filter to obtain N coefficient sets, and correcting the output two paths of amplitude difference and phase difference to inhibit virtual images through a method for assigning the N-1-order finite impact response filter.

Description

technical field [0001] The present invention relates to a signal processing method, in particular to a method for suppressing and filtering a virtual image in a complex signal processing mode and its realization circuit. With minimal hardware overhead and without interrupting normal signal processing, the adaptive correction matching changes quadrature circuit. Background technique [0002] In modern communication systems, the receiver is the most critical core. From the perspective of intermediate frequency output, the receiver mainly includes different structures suitable for real signal processing and complex signal processing. From the perspective of real signal processing, the receiver structure is as follows: figure 1 As shown, the local oscillator frequency of the received signal: f LO = f RF + f IF , virtual image frequency: f IMG = f RF +2f IF . This traditional real signal processor cannot distinguish between signals and virtual images (such as figure 2 ...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): H04L25/03
Inventor 何程明
Owner TIANJING YIRONG TECH
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