JP2012060485A - Radio receiver and radio reception method - Google Patents

Abstract

A radio receiver and a radio reception method capable of detecting noise superimposed on an AM signal at low cost.
A radio receiver according to the present invention includes an AM band limiting filter, an FM band limiting filter, an AM detector, an FM detector, a noise determination unit, and a noise processing unit. The AM band limiting filter 10 passes the AM band signal among the IF signals generated from the received AM signal. The FM band limiting filter 14 passes the FM band signal among the IF signals. The AM detector 11 detects the amplitude change amount of the AM band signal. The FM detector 15 detects the frequency change amount of the FM band signal. The noise determination unit 12 determines whether noise is superimposed on the IF signal based on the frequency change amount detected by the FM detector. When the noise determination unit 12 determines that noise is superimposed on the IF signal, the noise processing unit 13 removes the noise.
[Selection] Figure 1

Description

  The present invention relates to a radio receiver, and more particularly to a radio receiver and a radio reception method for receiving AM (Amplitude Modulation) broadcasting.

  Various external noises are superimposed on the radio broadcast wave during the transmission process, and the sound quality is deteriorated when the sound is demodulated by the radio receiver. In particular, in-vehicle radio receivers have many noise factors such as changes in radio wave conditions accompanying movement and ignition motors mounted on vehicles.

  Therefore, a radio receiver generally includes a mechanism for detecting and removing noise included in a received signal for the purpose of suppressing deterioration in sound quality due to external noise.

  Patent Document 1 discloses an AM receiver having a noise detection mechanism. FIG. 8 shows a block diagram of a part of the AM receiver described in Patent Document 1. In FIG. The AM signal received by the antenna is converted into an IF (Intermediate Frequency) signal (not shown). The AD converter (ADC) 105 converts the IF signal into a digital signal. A DDC (Digital Down Converter) circuit 106 performs frequency conversion and complex conversion of the digital signal to generate an I (In-phase) signal and a Q (Quadrature-phase) signal. The generated I signal and Q signal are supplied to the AM detector 110 and the noise detection circuit 200.

  The Δθ arithmetic circuit 210 included in the noise detection circuit 200 has a change amount per unit time of the phase θ on the complex plane of the I signal and the Q signal obtained by the DDC circuit 106 (hereinafter referred to as “phase change amount Δθ”). Is detected. When the phase change amount Δθ changes sharply, the noise detection circuit 200 determines that pulse noise has been detected in the received AM signal. The noise detection circuit 200 outputs a noise detection signal DET when pulse noise is detected. Through the above processing, noise superimposed on the AM signal is detected.

JP 2007-251907 A

  However, the AM receiver described in Patent Document 1 needs to newly provide a phase change Δθ calculation mechanism (noise detection circuit 200) in order to detect noise superimposed on the AM signal. As a result, there has been a problem that the cost of the radio receiver is increased.

  The radio receiver according to the present invention includes an AM band limiting filter that allows an AM band signal to pass among IF signals generated from a received AM signal, and an FM band limiting filter that allows an FM band signal to pass among the IF signals. An AM detector that detects an amplitude change amount of the AM band signal, an FM detector that detects a frequency change amount of the FM band signal, and the frequency change amount detected by the FM detector, Noise determining means for determining whether noise is superimposed on the IF signal, and noise processing means for removing the noise when the noise determining means determines that noise is superimposed on the IF signal, It is to be prepared. With such a configuration, noise detection can be performed using the detection result of the FM detector.

  According to the radio reception method of the present invention, an AM band signal is extracted from an IF signal generated from a received AM signal, an FM band signal is extracted from the IF signal, and an amplitude change amount of the AM band signal is extracted. And detecting a frequency change amount of the FM band signal, determining whether noise is superimposed on the IF signal based on the detected frequency change amount, and superimposing noise on the IF signal. If it is determined that the noise is present, the noise is removed. With such a configuration, noise detection can be performed using the detection result of the FM detector.

  According to the present invention, it is possible to provide a radio receiver and a radio reception method capable of detecting noise superimposed on an AM signal at low cost.

1 is a block diagram of a radio receiver according to a first exemplary embodiment. 1 is a block diagram of an FM detector according to a first embodiment. 1 is a block diagram of a complex conversion circuit according to a first exemplary embodiment; FIG. 3 is a waveform diagram showing an operation of the radio receiver according to the first exemplary embodiment. FIG. 3 is a block diagram of a radio receiver according to a second exemplary embodiment. FIG. 6 is a waveform diagram showing an operation of the radio receiver according to the second exemplary embodiment. It is a figure which shows the filter characteristic of FM band-limiting filter and AM band-limiting filter. It is a block diagram of a related radio receiver.

Embodiment 1
Embodiments of the present invention will be described below with reference to the drawings. A configuration example of a radio receiver 1 according to the present embodiment is shown in FIG. The radio receiver 1 includes an AM band limiting filter 10, an AM detector 11, a noise determination unit 12, a noise processing unit 13, an FM (Frequency Modulation) band limiting filter 14, and an FM detector 15.

  The configuration for converting the frequency of the received signal received by the antenna into an IF signal is a well-known configuration and will not be described. In addition, in the following description, it is assumed that an AM signal is selected in a front end (not shown) provided on the upstream side (antenna side) in order to describe a case where AM radio broadcasting is received. That is, the IF signal S1 in FIG. 1 includes only the AM signal.

  The AM band limiting filter 10 and the FM band limiting filter 14 extract a signal in a desired frequency band from the IF signal. Specifically, the AM band limiting filter 10 extracts an AM frequency band signal (AM band signal S2) from the IF signal. The FM band limiting filter 14 extracts an FM frequency band signal (FM band signal S6) from the IF signal.

  The AM detector 11 detects the amplitude change amount of the AM band signal S2 extracted by the AM band limiting filter 10. The FM detector 15 detects the frequency change amount of the FM band signal S6 extracted by the FM band limiting filter 14.

A specific detection process of the FM detector 15 will be described with reference to FIG. FIG. 2 is a diagram illustrating a configuration example of the FM detector 15. The FM detector 15 includes a complex conversion circuit 150, a division circuit 151, a Tan- ¹ circuit 152, and a phase angle shift extraction circuit 153.

  The complex conversion circuit 150 performs complex conversion on the IF signal and separates it into an I signal and a Q signal. FIG. 3 shows a specific configuration example of the complex conversion circuit 150. The complex conversion circuit 150 illustrated in FIG. 3 includes a delay circuit 1501 and a Hilbert filter 1502. The IF signal (FM band signal S6) is supplied to each of the delay circuit 1501 and the Hilbert filter 1502. The Hilbert filter 1502 shifts the phase of the IF signal by 90 degrees. On the other hand, the delay circuit 1501 gives the IF signal a delay equivalent to the delay required to pass through the Hilbert filter 1502 without changing the phase of the IF signal. As a result, the IF signal is separated into an I signal and a Q signal having a phase difference of 90 degrees.

The division circuit 151 divides the Q signal by the I signal and outputs the result to the Tan- ¹ circuit 152. The Tan ⁻¹ circuit 152 calculates Tan ⁻¹ as a division result, and calculates the phase angle between the I signal and the Q signal. The phase angle deviation extraction circuit 153 extracts the amount of change in the phase angle and calculates the frequency deviation of the IF signal. Thereby, the FM detection signal S7 is generated.

  An FM detection signal S7 detected by the FM detector 15 is input to the noise determination unit 12. The noise determination unit 12 determines whether noise is superimposed on the reception signal based on the FM detection signal S7. Specifically, when there is a change in the FM detection signal S7, the noise determination unit 12 determines that noise is superimposed on the received signal. Actually, the FM detection signal S7 always fluctuates due to minute noise. For example, when the absolute value of the amplitude of the FM detection signal S7 is equal to or greater than a predetermined value, it is determined that noise is superimposed on the received signal. To do. The predetermined value is appropriately set according to the characteristics of the filter. Furthermore, the noise determination unit 12 outputs a noise detection signal S5 to the noise processing unit 13 in order to notify the noise section.

  The noise processing unit 13 removes noise from the AM detection signal S3 output by the AM detector 11 in a section in which the noise determination unit 12 determines that noise is superimposed on the received signal. As a noise removal method, for example, an existing method such as linear interpolation or mute processing may be used.

  Next, the AM reception operation of the radio receiver 1 will be described with reference to the block diagram of FIG. 1 and the waveforms shown in FIG. First, the IF signal S <b> 1 generated from the received signal is supplied to the AM band limiting filter 10 and the FM band limiting filter 14. Here, the section a shown in FIG. 4 shows a section where noise is superimposed on the received signal. For this reason, the waveform of the IF signal S1 is disturbed in the section a.

  The AM band limiting filter 10 passes the AM band signal S2 included in the IF signal S1. On the other hand, the FM band limiting filter 14 passes the FM band signal S6 included in the IF signal S1. Here, the filter characteristics of the AM band limiting filter 10 and the FM band limiting filter 14 are shown in FIG. In Japan, the FM frequency allocation step is 200 kHz. On the other hand, the AM frequency allocation step is 9 kHz. Therefore, the FM band limiting filter 14 is an IF filter of about ± 125 kHz. On the other hand, the AM band limiting filter 10 is an IF filter of about ± 3 kHz.

  That is, the FM band limiting filter 14 passes an IF signal having a wider frequency band than the AM band limiting filter 10. In addition, as described above, the IF signal S1 is an AM signal having a narrower frequency band than the FM signal. Therefore, the FM band limiting filter 14 also passes the IF signal S1 that is an AM signal. Therefore, the AM band signal S2 that has passed through the AM band limiting filter 10 and the FM band signal S6 that has passed through the FM band limiting filter 14 are similar signals having a constant frequency.

  The AM detector 11 detects the AM band signal S2 on which noise is superimposed. As shown in FIG. 4, the AM detection signal S3 after detection is also affected by noise in the vicinity of the section a. The AM detector 11 outputs the AM detection signal S3 to the noise processing unit 13.

  On the other hand, the FM detector 15 detects the FM band signal S6. Here, in the AM signal, the amplitude changes, but the frequency is constant. That is, when no noise is superimposed, there is no substantial variation in the frequency of the FM band signal S6, and thus no phase angle shift occurs. As a result, the output of the phase angle shift extraction circuit 153, that is, the FM detection signal S7 output from the FM detector 15 is substantially zero.

  However, when noise is superimposed on the received signal, the frequency is not constant in the section where the noise of the FM band signal S6 is superimposed. Therefore, as shown in FIG. 4, the FM detector 15 detects the amount of change in frequency in the section a, and the FM detection signal S7 varies from 0. Then, the FM detection signal S7 is supplied to the noise determination unit 12.

  The noise determination unit 12 determines that a section where the FM detection signal S7 changes from 0 to a predetermined value or more is a section where noise is superimposed. Specifically, when the absolute value of the amplitude of the FM detection signal S7 is smaller than a predetermined value, the noise determination unit 12 determines that no noise is superimposed and outputs a low level noise detection signal S5. On the other hand, if the absolute value of the amplitude of the FM detection signal S7 is greater than or equal to a predetermined value, it is determined that noise is superimposed, and a high-level noise detection signal S5 is output. The noise detection signal S5 is supplied to the noise processing unit 13. In FIG. 4, the FM detection signal S7 swings in the negative direction after swinging in the positive direction. For this reason, the absolute value of the amplitude of the FM detection signal S7 is equal to or less than a predetermined value during a minute period in which the absolute value of the amplitude is near zero. Therefore, in actuality, the noise detection signal S5 is at a low level in the minute period. However, for example, the noise detection signal S5 in which the level of the period in which the amplitude of the FM detection signal S7 is changing becomes a high level can be acquired by performing processing that invalidates the fluctuation of the level in a minute period. .

  The noise processing unit 13 performs noise removal processing on the AM detection signal S3 in a section longer than the section a where the noise detection signal S5 is at a high level. The reason why the noise processing unit 13 performs the noise removal process in the section longer than the section a will be described below.

  As described above, in Japan, an AM broadcast is assigned a broadcast wave frequency at an interval of 9 kHz. Therefore, the AM broadcast is generally configured with a filter having a range of about ± 3 kHz with respect to the center frequency of a desired station frequency. Is. For this reason, the AM band limiting filter 10 is configured by a filter having a narrower pass band than the FM band limiting filter 14 (see FIG. 7).

  When the IF signal passes through a filter having a narrow pass band, the noise superimposed on the IF signal S1 is expanded temporally (in the horizontal axis direction in FIG. 4) when passing through the AM band limiting filter 10, and the noise period of the detection signal is also increased. Will expand. On the other hand, the FM band limiting filter 14 is not as narrow as the AM band limiting filter 10, so the above problem does not occur. As a result, in FIG. 4, when comparing the noise intervals of the AM detection signal S3 and the FM detection signal S7, the AM detection signal S3 has a longer noise interval.

  Therefore, the noise processing unit 13 executes noise removal processing in a section longer than the High level section a of the noise detection signal S5. This section is determined in advance according to the characteristics of the AM band limiting filter. Thereby, the noise process part 13 can perform noise removal in the whole area of the noise which has arisen in AM detection signal S3. The AM detection signal S4 illustrated in FIG. 4 is a signal obtained by noise removal by the noise processing unit 13. A portion indicated by a broken line is a section where noise processing is performed.

  As described above, according to the configuration of the radio receiver 1 according to the present embodiment, the FM detector 15 detects the FM band signal S6 and detects noise during AM reception. And the noise determination part 12 determines with the area where the frequency is changing the area where the frequency is changing from the result of FM detection. On the other hand, a general radio receiver includes an AM detector 11 and an FM detector 15. That is, according to the present invention, it is not necessary to separately provide a noise detection mechanism for noise detection, and therefore noise detection can be realized at low cost.

  Further, when the technique of Patent Document 1 is applied to a radio receiver that does not require complex conversion in the path leading to AM detection, complex conversion of the IF signal is necessary to calculate the phase change amount Δθ. Therefore, it is necessary to provide a complex conversion mechanism (DDC circuit 106) in addition to the phase change amount Δθ calculation mechanism (noise detection circuit 200). That is, it is necessary to further provide a mechanism for separating the I signal and the Q signal upstream of the AM detector in order to perform noise detection. However, according to the present invention, the I signal and the Q signal are not required for noise detection, so that the present invention can also be applied to AM detection (for example, envelope detection) that is not separated into the I signal and the Q signal.

Embodiment 2
A second embodiment according to the present invention will be described. FIG. 5 shows a configuration example of the radio receiver 2 according to the present embodiment. The radio receiver 2 is different from the radio receiver 1 shown in FIG. 1 in the arrangement of the noise processing unit 13, but the rest is the same. Therefore, description of the processing of each component is omitted.

  The noise processing unit 13 is provided on the upstream side (antenna side) of the AM band limiting filter 10. Therefore, the noise processing unit 13 removes noise from the IF signal S1 before the AM band limiting filter 10 extracts the AM band signal S9.

  Next, an AM reception operation of the radio receiver 2 according to the present embodiment will be described with reference to FIG. As in the first embodiment, the IF signal S1 passes through the FM band limiting filter 14. Then, the FM detector 15 detects the FM band signal S6. The noise determination unit 12 determines a section a where noise is superimposed based on the FM detection signal S7.

  On the other hand, in the present embodiment, the noise processing unit 13 includes the section a (High level section) of the noise detection signal S5 output from the noise determination section 12 before the IF signal S1 passes through the AM band limiting filter 10. ), Noise superimposed on the IF signal is removed.

  Thereafter, the IF signal S8 from which the noise has been removed passes through the AM band limiting filter 10. The AM detector 11 detects the AM band signal S9. With the above operation, the AM detection signal S10 from which noise is removed is output (the broken line portion is a noise processing section).

  Thus, according to the configuration of the radio receiver 2 according to the present embodiment, the noise processing unit 13 removes the noise of the IF signal S1 before the IF signal S1 passes through the AM band limiting filter 10. Therefore, the noise processing unit 13 can remove the noise before the noise section superimposed on the received signal is expanded by passing through the AM band limiting filter 10. That is, the noise processing unit 13 can perform noise removal before the noise section is shorter, in other words, before the influence of noise on the received signal becomes large. As a result, an AM detection signal with less distortion can be acquired.

  The present invention is not limited to the above-described embodiment, and can be appropriately changed and combined without departing from the spirit of the present invention. For example, the configuration of the FM detector 15 is not limited to the configuration shown in FIGS. 2 and 3, and any configuration that can detect the frequency shift of the IF signal may be used.

1, 2 Radio receiver 10 AM band limiting filter 11 AM detector 12 Noise determining unit 13 Noise processing unit 14 FM band limiting filter 15 FM detector 150 Complex conversion circuit 151 Dividing circuit 152 Tan ^-1 circuit 153 Phase angle shift extraction Circuit 1501 delay circuit 1502 Hilbert filter

Claims (6)

An AM band limiting filter that passes an AM band signal among IF signals generated from the received AM signal;
Among the IF signals, an FM band limiting filter that allows FM band signals to pass;
An AM detector for detecting an amplitude change amount of the AM band signal;
An FM detector for detecting a frequency change amount of the FM band signal;
Noise determining means for determining whether noise is superimposed on the IF signal, based on the frequency change amount detected by the FM detector;
If the noise determination means determines that noise is superimposed on the IF signal, noise processing means for removing the noise;
With radio receiver.   The radio receiver according to claim 1, wherein the noise processing unit removes the noise from the amplitude change amount detected by the AM detector. The FM band limiting filter passes a signal in a wider frequency band than the AM band limiting filter,
The radio receiver according to claim 1, wherein the noise processing means removes the noise from the IF signal before the IF signal passes through the AM band limiting filter.   The radio receiver according to claim 1, wherein the noise determination unit determines that noise is superimposed on the IF signal when a frequency change detected by the FM detector is equal to or greater than a predetermined value. When the noise determination means determines that noise is superimposed on the IF signal, it outputs a first level signal;
The radio receiver according to claim 1, wherein when it is determined that no noise is superimposed on the IF signal, a second level signal is output. Extract the AM band signal from the IF signal generated from the received AM signal,
Extracting the FM band signal from the IF signal,
Detecting an amplitude change amount of the AM band signal;
Detecting a frequency change amount of the FM band signal;
Based on the detected frequency change amount, it is determined whether noise is superimposed on the IF signal,
A radio reception method for removing noise when it is determined that noise is superimposed on the IF signal.

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