KR100736558B1 - Method and apparatus of processing phase-modulated signal in a receiver - Google Patents

Abstract

The present invention relates to a wireless communication device, and more particularly to a radio wave wireless communication system. To this end, a method of processing a phase-modulated signal in a receiving channel and a method of separating and processing an input signal amplified in two channels are provided. The first channel processes the instantaneous current value of the amplified input signal, thereby extracting useful signals from the amplified input signal, including the distortions due to amplitude-to-phase conversions occurring in the input amplifier. The second channel produces a signal proportional to the current power of the amplified input radio-frequency signal. Of course, this signal is converted into a signal corresponding to the current power of the input signal input to the amplifier in the carrier frequency service band of the input signal. The output signal of the first channel is processed using the information of the signal of the second channel and the amplitude-phase characteristic, thereby removing phase distortion from the output signal of the first channel. Therefore, the resultant useful output signal substantially matches the received valid signal. The present invention also includes a functional unit for performing the above method.

Mobile communications, modulation, phase, narrowband, RF

Description

Phase modulated signal processing method and phase modulated signal processing apparatus in a receiver {Method and apparatus of processing phase-modulated signal in a receiver}

1 is a block diagram of an apparatus for processing a phase modulated signal in a reception channel according to an embodiment of the present invention.

The present invention relates to a wireless communication device.

Three methods are commonly used to process received signals using various kinds of heterodyne circuits. These methods are commonly characterized by processing phase or frequency modulated signals in the receiving channel. This is explained in order as follows.

In the first method, the received signal passing through the radio-frequency (RF) bandpass filter is amplified and then subjected to one-time or double processing by using heterodyne demodulation (SIDinges.Mobile Communication: DECT technology.M Solon-press, 2003. See pages 115-132).

An apparatus for processing a phase modulated signal according to this first scheme includes at least one serially connected input filter (pre-selector filter), a low-noise input filter, one or two. Heterodyne, intermediate frequency amplifier, and demodulator.

Techniques of the first approach based on the use of heterodynes sometimes have insufficient dynamic range. Therefore, when the preselector filter fails to attenuate the strong noise signal to a satisfactory level, the unattenuated strong noise signal is input to the amplifier to operate the amplifier in the nonlinear mode.

The result is a strong distortion of the effective signal or a noisy signal, which broadens the spectrum of the noise signal. A similar situation arises when the use of a preselector filter is undesirable for some reason (e.g. large size, high cost).

 In the second method, after the received signal is amplified, the in-phase and quadrature components of the received signal are separately processed. It is then digitally converted to obtain a demodulated useful signal at the output. Thus, an apparatus used for phase or frequency modulated signal processing includes a low noise input amplifier whose output stage is connected to two channels for processing an amplified input signal.

Each channel is equipped with a heterodyne unit. The intermediate frequency signal applied to the heterodyne of the first channel has a phase shift of 90 degrees with the intermediate frequency signal applied to the heterodyne of the second channel. Appropriate phase-shifting units must be used for this purpose (see US Pat. No. 5398002 NKI 329/302, MKI NO3D3 / 00, 14.05.1995).

In the second method, the strong input noise signal causes strong distortion of the effective signal, and strict requirements on the performance of the receiving channel elements are required to remove the noise signal.

Finally, the third method involves direct conversion of a signal, and after the received signal is amplified, the frequency band (which is a frequency band corresponding to the carrier frequency operating band of the received signal) is removed from the amplified signal. Then, the final auxiliary signal is excluded from the amplified signal.

The obtained signal is demodulated and digitized. Accordingly, an apparatus for processing a phase or frequency modulated signal includes a preselector filter, a low-noise amplifier, an active delay line, an active band-elimination filter, and a subtractor. Subtracting unit, demodulator, heterodyne, adjustable gain amplifier, automatic gain control circuit, low-pass filter, analog-to-analog-to -digital converter), and digital processing (DNIvlev's "specificity related to the reception of phase-modulated signals in the presence of strong additional noise signals exceeding the receiver's operating range". Vestnik Nizhegorodskogo universiteta im. NI Lobachevskogo. "Radiophisics series" .Issue 1 (2), 2004. p.111-118 (in Russian)).

This scheme provides a technique for successfully receiving a narrowband phase modulated signal even in the state where additional strong narrowband noise signals exceeding the operating range of the receiver are mixed. In other words, this third technique removes noise other than the signal and maintains a constant signal size into the ADC by using AGC (Automatic Gain Control) to eliminate distortion caused by other signals or noise due to signal demodulation. Remove That is, even when a strong narrowband noise signal exceeding the operating range (dynamic range) is additionally mixed, the narrowband phase modulated signal can be successfully received.

However, the low noise amplifiers that form part of the receiver must have very low levels of amplitude-phase conversion in nonlinear mode of operation, which is practically difficult to obtain without the use of expensive amplifiers or filters.

On the other hand, incorporating a significant level of amplitude-phase conversion into the amplifier leads to random distortion on the information signal phase in the presence of a strong noise signal, resulting in distortion of the transmitted information.

Therefore, in mobile communication and wireless broadcasting systems, there is a demand for the development of effective means for ensuring good reception of input signals and processing phase modulated signals while extracting valid signals from the input signals with only minimal distortion of the valid signals.

Therefore, the present invention includes a strong narrow-band noisy signal exceeding the receiver's dynamic range, including amplitude-phase conversion, while the received signal is amplified. The purpose of the present invention is to provide a device and a phase modulation processing method for guaranteeing a good reception state of a narrow-band phase modulated signal.

The present invention also provides a phase modulation processing method that can be realized based on a combination of functions of a general element, and a low noise amplifier which processes this phase modulation and has a high level of amplitude-phase conversion at the signal input stage, while also receiving signals. Another aim is to provide a device capable of good quality treatment of the product.

In order to achieve the above object, the present invention, the input signal is amplified by an input amplifier for processing the input signal amplified in two different channels, the instantaneous current of the amplified input signal is processed in the first channel, the duration is The power value of the amplified input signal averaged in the watch window section not shorter than one oscillation period of the input signal is processed in the second channel and the input valid signal when the amplified input signal is processed in the first channel. The frequency band corresponding to the service band of the carrier frequency is removed from the amplified input signal, and then the synthesized auxiliary signal of the first channel is a combined signal of the effective signal and the phase noise signal, subtracted from the amplified input signal, and then demodulated. And then digitally converting at the first channel output stage to obtain a first channel output signal and amplifying the input signal when processing the input signal amplified in the second channel. Is converted into a second channel auxiliary signal proportional to the current power of the input signal within the watch window section, and then digitally converted, and then the data regarding the distortion generated during the processing of the auxiliary signal and amplification of the received current signal in the second channel. Obtaining a second channel output signal indicative of the input signal strength of the input stage of the input amplifier by using a second amplifier and phase noise from the first channel output signal using information on the amplitude-phase characteristics of the input amplifier and the second channel output signal. The present invention provides a method of processing a phase modulated signal in a receiver comprising removing and processing a signal.

In addition, the sampling periods for digitally converting the signals in the first channel and the second channel are the same.

Preferably, the signals in the first channel and the second channel are characterized in that the digital conversion at the same time.

Preferably, the phase distortion and / or time delay occurring during the processing of the amplifying current in the first channel and before removing the frequency band from the amplified current signal is performed. Characterized in that it is inserted into the amplified current signal.

Preferably, during the processing of the current signal amplified in the first channel and after performing the demodulation step, the frequency existing outside the service band of the modulating signal is removed from the demodulated signal. It is done.

 Further, the demodulated signal is amplified to a normalized level during processing of the current signal amplified in the first channel and before digital conversion of the demodulated signal.

Preferably, during signal processing in the second channel, the amplified current signal is continuously processed in a watch window section generating a continuous auxiliary signal of the second channel.

Furthermore, the method may further include removing a frequency located outside the service band of the auxiliary signal of the second channel from the continuous auxiliary signal of the second channel.

In addition, the continuous auxiliary signal of the second channel may be converted into an expanded auxiliary signal of the second channel to attenuate the nonlinear effect of the gain factor.

Furthermore, the method may further include removing a frequency located outside the service band of the extended auxiliary signal of the second channel from the extended auxiliary signal of the second channel.

Preferably, the auxiliary signal is amplified to a normalized level during signal processing of the second channel and before digital conversion of the auxiliary signal.

Furthermore, during signal processing in the second channel, the amplified current signal is continuously processed in the watch window section, resulting in a second channel auxiliary signal averaged in the watch window section.

Preferably, the duration in the watch window section is the same as the digital conversion sampling section of the signals of the first channel and the second channel.

In addition, according to one of the embodiments of the present invention, the method may further include removing a frequency located outside the service band of the auxiliary signal of the second channel from the auxiliary signal of the second channel.

Furthermore, the method may further include reducing the nonlinear effect of the gain factor by converting the auxiliary signal of the second channel into an expanded auxiliary signal of the second channel.

In addition, it is characterized in that the frequency located outside the service band of the extended auxiliary signal of the second channel from the extended auxiliary signal.

In addition, it is characterized in that the frequency located outside the service band of the extended auxiliary signal of the second channel from the extended auxiliary signal.

Preferably, the auxiliary signal is amplified to a normalized level during current signal processing in the second channel and before digital conversion of the auxiliary signal.

On the other hand, the present invention, an input amplifier for amplifying the input signal, and an input having a plurality of channels consisting of a first channel, a second channel connected to the output terminal of the input amplifier for processing the amplified input signal (Amplified input signal) A signal processing system comprising: a series connected band-elimination filter (BEF) for processing instantaneous current of an amplified input signal and removing a frequency band corresponding to a service band of a desired input signal from the amplified input signal; The second input has a subtractor connected to the output of the amplifier, a demodulator, and an analog-to-digital converter (ADC) for generating the output signal of the first channel, the second channel having a duration of one oscillation of the input signal. A digitally connected unit for processing the power value of the amplified input signal averaged within the watch window section not shorter than the period, and for generating an auxiliary signal of the second processing channel; An input signal processing system having a signal correction for correcting a second channel output signal, which is generated from the auxiliary signal and at the input stage of the input amplifier, the second channel output signal, which is a digitized auxiliary signal equal in input current and current strength, and an amplitude-phase characteristic of the input amplifier. And an output signal processor for removing a noise signal from the output signal of the first channel using the information on the output signal of the second channel and connecting the output signal of the first and second channels to process the output signal. An apparatus for processing a phase modulated signal in a receiving channel is provided.

On the other hand, the first channel is located between the amplifier and the second input terminal of the subtractor, characterized in that it has a correction shift unit for correcting the time and / or phase shift occurring in the band-elimination filter (BEF).

 In addition, the first channel may further include a filter located at the output of the demodulator and removing a frequency located outside the service band of the modulated signal.

In addition, the first channel may further include an amplifier in front of an analog-to-digital converter (ADC).

In addition, the second channel includes an expander positioned at an output terminal of the auxiliary signal generator that generates an auxiliary signal of the second channel, wherein the auxiliary signal is proportional to the current power of the input signal existing in the watch window section. .

In addition, the second channel may further include an amplifier located at an input of an analog-to-digital converter (ADC).

Therefore, according to the present invention, it is possible to improve the quality of signal reception from the influence of a strong noise signal in an airwave communication system such as a mobile communication or a wireless broadcast receiver. In addition, it is possible to reduce the volume of the receiving module and to avoid the use of expensive passive filters from the wireless communication system circuit and to reduce the influence on the quality of the effective signal during amplitude-phase conversion in the input amplifier.

Hereinafter, with reference to the accompanying drawings will be described in detail an embodiment according to the present invention.

1 is a block diagram of an apparatus for processing a phase modulated signal in a reception channel according to an embodiment of the present invention. Referring to FIG. 1, the phase modulation signal processing apparatus includes a reception channel 100, an input signal processing system 10, and an output signal processing unit 123.

The receiving channel 100 includes an antenna 101, a pre-selector filter (PSF) 102, and a low-noise amplifier (LNA) 103. Here, the PSF (preselector filter) can be omitted in construction.

The input signal processing system 10 is connected to the output of the LNA 103 and includes two channels 4 and 5 for processing an amplified input signal.

Here, the PSF 102 can be omitted in construction, and the LNA is called a low noise amplifier. And an output signal processor 123 for processing a signal output from the two channels 4 and 5 to generate a final output signal.

Here, the channel is composed of a first channel 4 and a second channel 5, each channel performs a different function. That is, the first channel 4 processes the instantaneous current value of the amplified input signal, thereby extracting useful signals from the amplified input signal including distortions due to amplitude-to-phase conversion occurring in the input amplifier. On the other hand, the second channel 5 generates a signal proportional to the current power of the amplified input radio-frequency signal. Of course, this signal is converted into a signal corresponding to the current power of the input signal input to the amplifier in the carrier frequency service band of the input signal.

Therefore, when the output signal converted through the first channel 4 and the second channel 5 are combined, the original received signal information can be extracted without distortion.

That is, in the signal extraction process of the first channel 4, since the amplitude is the same, there is no signal distortion because the load of the related device due to the excessive signal is small. In addition, since the second channel 5 only needs to determine that the signal has a small amplitude with respect to the minute signal input, the input signal does not need to be excessively amplified to recognize the minute signal. As a result, there is no need to process signals with excessive amplitudes, so no distortion occurs.

As described in the prior art, if the channel is not separated, if the gain is amplified for gain of frequency or phase information of the fine signal, the input signal is also amplified by the gain, so that an analog-to-digital converter (ADC) As the dynamic range of the signal level to be processed increases, the signal information is lost because it is out of the range processed by the ADC.

Therefore, in one embodiment of the present invention for this purpose, each channel has a different component. First, the first channel 4, the first channel 4 is a band-elimination filter (BEF) 106, a subtracting unit (107), a modulator 109, a low-pass filter (LPF) 110 And a variable gain amplifier 111.

The BEF 106 performs a function of removing a frequency band corresponding to a service band of a received input signal carrier frequency from the amplified input signal as a band-elimination filter. Perform.

The subtractor 107 subtracts the signal output from the BEF 106 from the delayed signal from the delay line 108. To this end the first input of subtractor 107 is connected to BEF 106 and the second input is connected to the output of LNA 103 via delay line 108. The delay line 108 performs a function of correcting a shift of the amplified input signal in time or in phase.

This subtractor 107 is connected in series with the demodulator 109 and the LPF 110. Of course, the LPF 110 is matched with the variable gain amplifier 111 to remove the frequency outside the service band of the modulated signal. The variable gain amplifier 111 is connected to an automatic gain control 112 and an analog-to-digital converter 113 located on a feedback line, and output signals of the first channel 4. Is converted from analog to digital form by the ADC 113. Here, a heterodyne 114 is configured to control the demodulator 109.

Next, the second channel 5 will be described. The second channel 5 generates an instantaneous current value of an amplified input signal averaged in a watch window period in which at least one oscillation period is processed. To this end, the second channel 5 includes an auxiliary signal generator 115 for generating an auxiliary signal of the second channel 5, an expander 116, an LPF 117, and a variable gain amplifier 118. It includes. Here, the auxiliary signal of the second channel 5 is proportional to the input signal power in the watch window section.

The variable gain amplifier 118 preferably uses a matching variable-gain amplifier, and includes an automatic gain control unit 119 and an analog-to-ADC located in a feedback line. digital converter 120. Accordingly, the ADC 113 converts the auxiliary signal of the second channel 5 into digital and transmits it to the signal correction unit 121.

The signal compensator 121 corrects this digitized auxiliary signal to generate a digital output signal of the second channel 5. At this time, this digital output signal is equivalent to the current with respect to the input signal of the LNA 103. Of course, the memory unit 122 is connected to the signal compensator 121 for generating the output signal. Alternatively, the memory 122 may be included in the signal corrector 121 without separately configuring the memory 122. The memory unit 122 includes information on the amplitude-phase characteristic of the LNA 103 and the like.

The input signal processing system 10 including the first channel 4 and the second channel 5 is connected to the output signal processing unit 123. That is, the output signal processor 123 is connected to the ADC 113 of the first channel 4 and the signal compensator 121 of the second channel 5, respectively.

Therefore, the output signal processor 123 processes the first channel output signal of the first channel 4 and the second channel output signal of the second channel 5 to generate a final output signal. Of course, the memory unit 124 may be connected or embedded in the output signal processor 123 as described above.

Referring to the signal processing up to the output signal processor 123, the input signal received by the antenna 101 is first amplified through the LNA 103 and then to the first channel 4 and the second channel 5. Delivered and processed. In particular, it is a process applied to a digital noise-proof receiving channel for processing a phase modulated signal.

In the first channel 4, the amplified input signal is transmitted to the BEF 106 and the delay line 108 and then input to the subtractor 107. Of course, as described above, the subtractor 107 removes the amplified input signal transmitted through the BEF 106 from the amplified input signal transmitted through the delay line 108.

The signal output from the subtractor 107 is input to the demodulator 109. Although the demodulator 109 preferably uses a quadrature demodulator that divides a signal into in-phase and quadrature components, it is implemented using a single channel demodulator. It is also possible.

The signal demodulated by the demodulator 109 passes through the LPF 110, the variable gain amplifier 111, and the ADC 113.

Meanwhile, in the case of the second channel 5, the input signal amplified by the LNA 103 is applied to the auxiliary signal generator 115 for generating an auxiliary signal of the second channel 5. At this time, the auxiliary signal of the second channel 5 is characterized by being proportional to the current power of the input signal within the watch window section.

The auxiliary signal generated by the auxiliary signal generator 115 is transmitted to the expander 116, the LPF 117, the variable gain amplifier 118, the ADC 120, and the signal corrector 121. The signal compensator 121 receives the information on the power dynamic characteristics of the LNA 103 from the memory unit 122 and corrects the digitized auxiliary signal of the second channel 5 to thereby correct the second channel 5. Generate a second channel output signal of. The second channel output signal generated by the signal corrector 121 is a digitized output signal, and the current power of the output signal is equal to the current power of the input signal applied to the input terminal of the LNA 103.

Output signals (first channel output signal and second channel output signal) of the first channel 4 and the second channel 5 are applied to the output signal processor 123. Of course, at this time, the output signal processing unit 123 obtains the amplitude-phase characteristic information of the LNA 103 from the memory unit 124 and processes the output signals.

Therefore, when the amplitude-phase characteristic of the LNA 103 and the current power of the input signal input to the LNA 103 are known, the phase noise present in the first channel output signal of the first channel 4 is determined, and from this output signal, It becomes possible to eliminate phase noise. Therefore, it is possible to obtain the least distorted arc signal at the output terminal.

According to the present invention, the received input signal is processed in the first channel 4 and the second channel 5 which are reception channels in the following manner.

Antenna 101 receives a useful narrowband phase modulation information signal u ₁ (t) , which is an additive mixture of a strong narrowband noise signal and a relatively weak random noise.

The PSF (Pre-selector filter) 102 filters the input signal received from the antenna 101 to some extent, and the strong noise signal is not sufficiently removed even by this filtering.

The LNA 103 amplifies the input signal u ₂ (t) (a signal obtained by combining u ₁ (t) with a strong noise signal and a weak useful signal) and simultaneously limits the level of a strong noise signal. .

From the output of the LNA 103, an amplified input signal u ₃ (t) comprising an effective signal u ₁ (t) having a distorted amplitude and noise signals having an extended spectral region is input to the input signal processing system 10. do.

The amplified input signal u ₃ (t) is transmitted to the delay line 108 and the BEF 106 in the first channel 4. Therefore, the BEF 106 suppresses the effective input signal u ₁ (t) from the amplified input signal u ₃ (t) according to the frequency (the frequency band corresponding to the service band of the carrier frequency of the input signal). By doing so, the noise signals pass through the output of BEF 106.

The delay line 108 converts the phase spectrum of the effective signal u ₁ (t) whose amplitude is distorted and the input signal u ₃ (t) including the noise signal. At this time, the delay line 108 does not change the amplitude spectrum of the input signal u ₃ (t) in the same manner as the BEF 106.

The subtractor 107 removes the noise signal output from the BEF 106 from the output signal of the delay line 108. Accordingly, the signal u ₇ (t) output from the subtractor 107 is a distortion of the effective signal u ₁ (t) and the noise signal generated in the effective signal band and incomplete filtering due to the amplitude-phase correction effect of the LNA 103. This includes the small residual part of the noise.

On the other hand, when the input values of the delay line 108 and the BEF 106 are compared, it is possible to calculate the degree of attenuation of the effective signal at the output of the subtractor 107. The attenuation degree of the valid signal is generated by the final value of the attenuation factor of the BEF 106, and can be expressed as Equation 1 below.

Here, α _dB is the attenuation factor of the BEF 106 in the elimination band and the display unit is decibel.

Therefore, if the attenuation factor α _dB is 30 _dB , the effective component of the extraction signal u ₇ (t) output from the subtractor 107 is reduced by 0.3 dB.

The demodulation of the extracted signal u ₇ (t) generated by this subtractor 107 is performed using a demodulator 109 that receives a signal from the heterodyne 114. The demodulated signal u ₉ (t) can be passed directly from the demodulator 109 to the ADC 113. Of course, a low pass filter (LPF), an amplifier, or the like is preferably configured between the demodulator 109 and the ADC 113 to further process the demodulated signal.

The LPF 110 serves to prevent spectral fold-over when the demodulated signal u ₉ (t) is digitally converted by the ADC 113. The variable gain amplifier 111 amplifies the signal to the level required by the ADC 113.

The ADC 113 converts the demodulated signal u ₉ (t) into the digital output signal u ₁₃ (t) (first channel output signal) of the first channel 4. The digital output signal u ₁₃ (t) of the first channel is input to the output signal processor 123.

On the other hand, the auxiliary signal generator 115 located in the second channel 5 converts the amplified input signal u ₃ (t) into an auxiliary signal u ₁₅ (t) proportional to the current power of the input signal. During generation of this auxiliary signal u ₁₅ (t), the watch window preferably has a duration τ of at least one oscillation period of the amplified input signal .

Therefore, an embodiment of the present invention proposes two schemes for generating this auxiliary signal u ₁₅ (t) .

In the first method, the RC-filter and diode are connected in series to continuously process the amplified input signal u ₃ (t) . Thus it is obtained an output signal u ₁₅ that is proportional to the power of the amplified input signal _{u 3 (t) (t)} . In the case of the first method, the duration τ of the watch window is much larger than one oscillation period of the amplified input signal.

In practice, this auxiliary signal u ₁₅ (t) represents the change in current power of the amplified output signal u ₃ (t) observed at the output of the LNA 103.

The auxiliary signal u ₁₅ (t) may be transferred directly from the auxiliary signal generator 115 to the ADC 120. Of course, it is preferable that the expander 116, the LPF 117, and the variable gain amplifier 118 be configured between the auxiliary signal generator 115 and the ADC 120 for further processing of the auxiliary signal u ₁₅ (t) . Do.

The decompressor 116 decompresses the non-linear conversion of the auxiliary signal u ₁₅ (t) to equalize the power ratio of the signal quantized by the ADC 120 with the power ratio of the quantization noise to the variation of the quantized signal values during different intervals. ). For this purpose, the expander 116 is preferably an anti-logarithmic amplifier.

The LPF 117 prevents spectral fold-over when the auxiliary signal u ₁₅ (t) is digitally converted by the ADC 120, similarly to the first channel 4 described above. Perform. The variable gain amplifier 118 amplifies the signal input from the LPF 117 to the level required by the ADC 120.

The ADC 120 converts the auxiliary signal u ₁₅ (t) into a digital signal u ₂₀ (t) as an analog-digital converter, and transfers the converted digital signal to the signal compensator 121.

The signal compensator 121 includes the dynamic characteristic of power of the LNA 103 stored in the memory unit 122 and a known value between the input power level and the output power level of the LNA 103. Relationship, and the digital signal u ₂₀ (t ) is converted into the output digital signal u ₂₁ (t) (the second channel output signal of the second channel 5) in consideration of the signal extension by the expander 116. . At this time, the output digital signal u ₂₁ (t) is proportional to the current power of the input signal u ₂ (t) input to the LNA 103. Here, the input signal u ₂ (t) is a signal present at the input of the LNA 103 within the carrier frequency band of the noise signal.

According to the second method for generating the auxiliary signal u ₁₅ (t) , the duration τ of the watch window is set in advance and may be at least one oscillation period of the amplified input signal. The duration τ of the watch window is preferably set equal to the sampling period for digitizing the signal in the first channel 4 and the second channel 5 of the input signal processing system 10.

The amplified input signal u ₃ (t) is processed by the auxiliary signal generator 115, which is an integrator. The integration of the amplified input signal u ₃ (t) is performed within the watch window period by the following equation (2).

u ₁₅ (t) is the output of the auxiliary signal generator 115 and depends on the current strength of the amplified input signal u ₃ (t) .

In fact, this auxiliary signal u ₁₅ (t) means the variable property of the current power of the output signal u ₃ (t) amplified at the output of the LNA 103. The auxiliary signal u ₁₅ (t) may be directly transmitted from the auxiliary signal generator 115 to the ADC 120, but the auxiliary signal u between the auxiliary signal generator 115 and the ADC 120 as described above. It is preferable to configure the expander 116, LPF 117, variable gain amplifier 118 to perform additional processing of ₁₅ (t) .

Here, the expander 116 performs nonlinear transformation of the auxiliary signal u ₁₅ (t) . Therefore, the auxiliary signal u ₁₅ (t) is equalized by the ADC 120 during the intensity of the quantized signal and the intensity ratio of the quantized noise during different intervals of the quantized signal values.

For this purpose, the expander 116 may use an anti-logarithmic amplifier.

The LPF 117 serves to prevent spectral fold-over when the auxiliary signal u ₁₅ (t) is digitally converted by the ADC 120 as in the first method described above.

The variable gain amplifier 118 amplifies the signal to the level required by the ADC 120. The ADC 120 converts the auxiliary signal u ₁₅ (t) into a digital signal u ₂₀ (t) , and the converted digital signal u ₂₀ (t) is transmitted to the signal corrector 121.

The signal correcting unit 121 converts the digital signal u ₂₀ (t) into an output digital signal u ₂₁ (t) (second channel output signal). At this time, the output digital signal u ₂₁ (t) is proportional to the current power of the input signal u ₂ (t) (in the carrier frequency band of the noise signal).

At this time, the signal correcting unit 121 is a dynamic characteristic of power of the LNA 103 stored in the memory unit 122, a known power between the input power level and the output power level of the LNA 103 ( The conversion of the output digital signal u ₂₁ (t) is performed in consideration of the relationship and the signal extension by the expander 116.

Through the above-described processing, the first channel output signal u ₁₃ (t) by the first channel 4 and the second output signal u ₂₁ (t) by the second channel 5 are transmitted to the output signal processor 123. Is entered.

The output signal processing unit 123 uses information on the amplitude-phase characteristics of the LNA 103 stored in the second channel output signal u ₂₁ (t ) of the second channel 5 and the memory unit 124 and their relationship. Thus, during nonlinear operation of the LNA 103 (phase shift in the service band of the input valid signal is generated by the amplitude-to-phase conversion of the LNA 103 with respect to a specific level of the signal present at the input of the LNA 103. Determine the phase shift of the effective signal. When the phase shift is determined, the output signal processing unit 123 removes this phase shift from the output digital signal u ₁₃ (t) (first channel output signal).

When the first channel output signal u ₁₃ (t) is processed by the output signal processing unit 123, all time delays known in the first channel 4 and the second channel 5 of the input signal system 10 ( time delay) is preferably taken into account.

Substantially, when the final output signal u ₂₃ (t) and the amplification valid signal differ only by the noise signal generated by incomplete filtering and the noise signal generated within the effective signal band, the final output signal u ₂₃ (t) is an amplification valid signal. Almost matches perfectly with

In order for the proposed method to be implemented, circuit components that are well applied in mass production, such as band-elimination filter, low-pass filter, low-noise amplifier, matching Circuit components such as matching variable-gain amplifiers, memory, and microprocessors are required. In the case of microprocessors in particular, they process incoming information according to known relationships. These known relationships are factors to be considered when determining the algorithm used to process data in the microprocessor.

As mentioned above, although this invention was demonstrated in detail using the preferable Example, the scope of the present invention is not limited to a specific Example, If the person who acquired the ordinary knowledge in this technical field, without departing from the range of this invention, It should be understood that many modifications and variations are possible. Therefore, the protection scope of the present invention will be preferably interpreted by the appended claims.

As described above, according to the present invention, it is possible to improve the quality of signal reception from the influence of a strong noise signal in an over-the-air communication system such as a mobile communication or a wireless broadcast receiver.

In addition, while reducing the volume of the receiving module, it is not necessary to use an expensive passive filter in the wireless communication system, and the input amplifier has an advantage of reducing the effect on the quality of the effective signal during the amplitude-phase conversion.

Claims (23)

The input signal is amplified by an input amplifier for processing the input signal amplified in two different channels, the instantaneous current of the amplified input signal is processed in the first channel, and the duration is one oscillation period of the input signal. Processing a power value of the amplified input signal averaged in a shorter watch-one window section in a second channel; When processing the amplified input signal in the first channel, the frequency band corresponding to the service band of the input valid signal carrier frequency is removed from the amplified input signal, and then the composite auxiliary signal of the first channel is combined with the valid signal. A phase noise signal is a synthesized signal, subtracted from the amplified input signal, demodulated, and then digitally converted at a first channel output stage to obtain a first channel output signal; When the amplified input signal is processed in the second channel, the amplified input signal is converted into a second channel auxiliary signal proportional to the current power of the input signal within the watch window section, and then digitally converted. Obtaining a second channel output signal indicative of the input signal strength of the input stage of the input amplifier by correcting using data relating to distortion during processing of the auxiliary signal in the second channel and amplification of the received current signal; And And removing and processing a phase noise signal from the first channel output signal using the information on the amplitude-phase characteristic of the input amplifier and the second channel output signal. Claim 2 was abandoned when the setup registration fee was paid. And a sampling period for digitally converting the signals in the first channel and the second channel is the same. Claim 3 was abandoned when the setup registration fee was paid. The method of claim 2, The method of claim 1, wherein the signals of the first channel and the second channel are digitally converted at the same time. Claim 4 was abandoned when the registration fee was paid. The method of claim 1, During the processing of the amplified current in the first channel and before performing the subtraction operation, the phase distortion and / or time delay which occurs in the step of removing the frequency band from the amplified current signal is the amplified current. A phase modulated signal processing method according to claim 1, wherein the receiver is embedded in a signal. Claim 5 was abandoned upon payment of a set-up fee. The method of claim 1, During the processing of the current signal amplified in the first channel and after performing the demodulation step, the frequency existing outside the service band of the modulating signal is removed from the demodulated signal. Phase modulated signal processing method in a receiver. Claim 6 was abandoned when the registration fee was paid. And the demodulated signal is amplified to a normalized level during processing of the current signal amplified in the first channel and before digital conversion of the demodulated signal. The method of claim 1, During signal processing in the second channel, an amplified current signal is continuously processed in a watch window section generating a continuous auxiliary signal of the second channel. . The method of claim 7, wherein And removing the frequency located outside the service band of the auxiliary signal of the second channel from the continuous auxiliary signal of the second channel. The method of claim 7, wherein And a continuous auxiliary signal of the second channel is converted into an expanded auxiliary signal of the second channel to attenuate the nonlinear effect of the gain factor. Claim 10 was abandoned upon payment of a setup registration fee. And removing a frequency located outside a service band of the extended auxiliary signal of the second channel from the extended auxiliary signal of the second channel. Claim 11 was abandoned upon payment of a setup registration fee. The method according to any one of claims 7 to 10, Wherein said auxiliary signal is amplified to a normalized level during signal processing of said second channel and prior to digital conversion of said auxiliary signal. Claim 12 was abandoned upon payment of a registration fee. The method of claim 1, In the receiver, during the signal processing in the second channel, the amplified current signal is continuously processed in the watch window section, and as a result, the second channel auxiliary signal averaged in the watch window section is generated. Phase Modulation Signal Processing Method. The method of claim 1, And a duration in the watch window section is equal to a digital conversion sampling section of the signals of the first and second channels. Claim 14 was abandoned when the registration fee was paid. And removing a frequency located outside a service band of the auxiliary signal of the second channel from the auxiliary signal of the second channel. Claim 15 was abandoned upon payment of a registration fee. The method of claim 13, And converting the auxiliary signal of the second channel into an expanded auxiliary signal of the second channel to reduce the non-linear effect of the gain factor. Way. Claim 16 was abandoned upon payment of a setup registration fee. The method of claim 15, And removing a frequency located outside a service band of the extended auxiliary signal of the second channel from the extended auxiliary signal. Claim 17 was abandoned upon payment of a registration fee. The method according to any one of claims 12 to 16, Wherein said auxiliary signal is amplified to a normalized level during current signal processing in said second channel and before digital conversion of said auxiliary signal. An input amplifier for amplifying the input signal; An input signal processing system connected to an output terminal of the input amplifier and having a plurality of channels including a first channel and a second channel for processing an amplified input signal, wherein the first channel is an instantaneous input of the amplified input signal. A series-connected band-elimination filter (BEF) for processing tooth current and removing a frequency band corresponding to the service band of the desired input signal from the amplified input signal, and a subtractor having a second input terminal connected to the output terminal of the amplifier; A demodulator and an analog-to-digital converter (ADC) for generating an output signal of a first channel, The second channel processes a power value of the amplified input signal averaged in a Watch One window section whose duration is not shorter than one oscillation period of the input signal, and is serial for generating an auxiliary signal of the second processing channel. An input signal processing system having a connected unit and a signal correction for correcting a second channel output signal, which is generated from a digital auxiliary signal and at the input of the input amplifier, a second channel output signal which is the same as the input signal and the current strength; By using the information on the amplitude-phase characteristics of the input amplifier and the output signal of the second channel to remove the noise signal from the output signal of the first channel, and connected to the output terminal of the first channel and the second channel to process the output signal A phase modulated signal processing apparatus in a receiver comprising an output signal processing unit for performing the same. The method of claim 18, The first channel is positioned between an amplifier and a second input terminal of the subtractor and has a phase shifting unit for correcting a time and / or phase shift occurring in a band-elimination filter (BEF). Signal processing device. The method of claim 18, And the first channel further includes a filter located at an output of a demodulator and removing a frequency located outside a service band of a modulated signal. Claim 21 was abandoned upon payment of a registration fee. The method of claim 18, And the first channel further comprises an amplifier in front of an analog-to-digital converter (ADC). The method of claim 18, The second channel includes an expander positioned at an output terminal of an auxiliary signal generator that generates an auxiliary signal of a second channel, and the auxiliary signal is proportional to a current power of an input signal existing in a watch window section. Phase modulated signal processing apparatus in the. Claim 23 was abandoned upon payment of a set-up fee. And said second channel further comprises an amplifier located at an input of an analog-to-digital converter (ADC).

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