JP2014216827A - Broadcast receiving device and signal processing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To accurately perform appropriate processing for reproduction according to a change in a reception environment such as multipath occurrence.SOLUTION: A noise reduction filter part 131 performs adaptive filtering processing to an intermediate frequency signal IFD to generate a signal FLD in which a noise included in the intermediate frequency signal IFD is reduced. A processing part 133 performs processing for reproduction to the detection result of the signal FLD. Upon performing the processing, a high-speed response control part in a control unit 190 quickly generates high-speed high-cut control designating a high-band attenuation ratio on the basis of error information between the intermediate frequency signal IFD and the signal FLD on which a change in a reception environment is reflected, and transmits it to a high-speed high-cut processing part in the processing part 133. Thus, it is possible to quickly perform the high-cut processing following the high-band attenuation ratio corresponding to the size of an error ERR.

Description

  The present invention relates to a broadcast receiving apparatus, a signal processing method, a signal processing program, and a recording medium on which the signal processing program is recorded.

  2. Description of the Related Art Conventionally, a broadcast receiving apparatus that receives and processes broadcast signals such as FM (Frequency Modulation) broadcasts and reproduces sound is mounted on a moving body such as a vehicle. In such a broadcast receiving apparatus, due to the movement of the moving body, the reception situation such as the received electric field strength in the frequency band of the desired broadcast signal and the amount of noise mixed in the signal to be detected changes. Therefore, an automatic reception control (ARC) function for changing a signal processing mode for audio reproduction in response to a change in reception status of a desired broadcast signal for a broadcast receiving device mounted on a mobile body (See Patent Document 1: hereinafter referred to as “conventional example”).

  In the conventional technique, the received electric field strength in the frequency band of the desired broadcast signal is detected by detecting the signal level of the intermediate frequency signal obtained by frequency conversion of the signal in the frequency band of the desired broadcast signal. Based on the detection result of the received electric field strength, control is performed for mute processing, so-called high cut processing, and separation processing for stereo reproduction, which is processing for reproduction of the detection result signal.

  Further, in the conventional technique, adaptive filtering processing is performed on the above-described intermediate frequency signal by a noise reduction filter, and noise in the intermediate frequency signal is reduced to generate a detection target signal. Detect the noise level. Based on the detection result of the noise level, the reproduction processing described above is controlled.

JP 2005-167718 A

  In the above-described conventional technique, the processing for reproduction is controlled based on the detection result of the signal level of the intermediate frequency signal and the detection result of the noise level in the detection target signal output from the noise reduction filter. However, there is a case where the correlation between the level detection result and the multipath distortion due to the occurrence of the multipath phenomenon in the detection target signal is small.

  In other words, in the conventional technique, multipath occurrence is detected from the noise component included in the electric field level. However, multipath occurrence may be erroneously detected by fluctuations in the electric field level due to other factors. Therefore, the correlation may be small.

  In order to reduce such false detections, the sensitivity for controlling the processing for reproduction must be set low. Moreover, in order to ensure the noise reduction effect, the maximum attenuation amount by the high cut filter used for the high cut processing has been set large. As a result, there is a concern that appropriate processing for reproduction corresponding to multipath distortion cannot be performed, such as concern about deterioration of high frequency components of reproduced audio.

  For this reason, a technique capable of performing appropriate reproduction processing corresponding to multipath distortion is desired. Meeting this requirement is one of the problems to be solved by the present invention.

  The present invention has been made in view of the above-described circumstances, and adopts a configuration including a noise reduction filter that performs adaptive filtering processing on an intermediate frequency signal while changing a reception state such as multipath generation. An object of the present invention is to provide a broadcast receiving apparatus and a signal processing method capable of accurately performing a corresponding processing for reproduction.

  The invention according to claim 1 is a broadcast receiving apparatus that receives a broadcast signal and performs signal processing, and uses an intermediate frequency signal obtained by frequency conversion of the broadcast signal as an input signal, and is adapted to the input signal. A noise reduction filter unit that outputs an output signal in which noise in the input signal is reduced by performing a general filtering process; a detection unit that detects the output signal of the noise reduction filter unit; and a detection by the detection unit A broadcast receiving apparatus comprising: a processing unit that performs processing for reproduction on a result; and a control unit that controls the processing unit based on error information between the input signal and the output signal. It is.

  In the invention according to claim 8, noise in the input signal is reduced by using an intermediate frequency signal obtained by frequency conversion of the broadcast signal as an input signal and applying an adaptive filtering process to the input signal. Broadcast comprising: a noise reduction filter unit that outputs an output signal; a detection unit that detects the output signal of the noise reduction filter unit; and a processing unit that performs a processing process for reproduction on a detection result of the detection unit. A signal processing method used in a receiving apparatus, wherein an acquisition step of acquiring error information between the input signal and the output signal; and processing for reproduction by the processing unit based on an acquisition result in the acquisition step And a control process for controlling the processing.

  The invention described in claim 9 is a signal processing program that causes a computer included in a broadcast receiving apparatus that receives a broadcast signal and performs signal processing to execute the signal processing method according to claim 8. .

  The invention according to claim 10 is characterized in that the signal processing program according to claim 9 is recorded so as to be readable by a computer included in a broadcast receiving apparatus which receives a broadcast signal and performs signal processing. It is a recording medium.

It is a block diagram which shows roughly the structure of the broadcast receiver which concerns on one Embodiment of this invention. It is a block diagram which shows the structure of the signal processing unit of FIG. It is a block diagram which shows the structure of the noise reduction filter part of FIG. It is a block diagram which shows the structure of the digital filter part of FIG. It is a block diagram which shows the structure of the adaptive control part of FIG. It is a block diagram which shows the structure of the process part of FIG. It is a block diagram which shows the structure of the control unit of FIG. It is a figure for demonstrating control of the process by the normal response control part of FIG. FIG. 8 is a diagram for explaining a change in a maximum attenuation designated value according to a change in an error amount in the high cut processing by the high-speed response control unit in FIG. 7. It is a figure for demonstrating the relationship between the control of the process of a high cut process by a normal response control part, and the control of the process of a high cut process by a high-speed response control part.

  Hereinafter, an embodiment of the present invention will be described with reference to FIGS. In the present embodiment, an FM stereo audio broadcast receiving apparatus will be described as an example. In the following description and drawings, the same or equivalent elements are denoted by the same reference numerals, and redundant description is omitted.

[Constitution]
FIG. 1 is a block diagram illustrating a schematic configuration of a broadcast receiving apparatus 100 according to an embodiment. In the following description, the name of the signal for the stereo audio left channel (hereinafter referred to as “L channel”) is appended with the suffix “L” for the right channel (hereinafter referred to as “R channel”). Subscript “R” is added to the names of signals.

As shown in FIG. 1, the broadcast receiving apparatus 100 includes an antenna 110 and an RF processing unit 120. In addition, the broadcast receiving apparatus 100 includes a signal processing unit 130, an analog processing unit 140, and speaker units 160 _L and 160 _R. Further, the broadcast receiving apparatus 100 includes an input unit 170 and a control unit 190.

  The antenna 110 receives a broadcast wave. A reception result by the antenna 110 is sent to the RF processing unit 120 as a reception signal RFS.

  The RF processing unit 120 performs channel selection processing for extracting the signal of the physical channel to be selected from the reception signal RFS in accordance with the channel selection command CSL sent from the control unit 190, and has a component in a predetermined intermediate frequency band An intermediate frequency signal IFD is generated. The intermediate frequency signal IFD thus generated is sent to the signal processing unit 130 and the control unit 190.

  In the present embodiment, the RF processing unit 120 includes an input filter, a high-frequency amplifier (RF-AMP: Radio Frequency-Amplifier), and a band-pass filter (hereinafter also referred to as “RF filter”). The RF processing unit 120 includes a mixer (mixer), an intermediate frequency filter (hereinafter also referred to as “IF filter”), and an AD (Analogue to Digital) converter (ADC). Further, the RF processing unit 120 includes a local oscillation circuit (OSC).

  In the RF processing unit 120, the received signal RFS transmitted from the antenna 110 is amplified by a high frequency amplifier after a low frequency component is cut off by an input filter. The signal amplified by the high frequency amplifier is mixed with the local oscillation signal generated by the local oscillation circuit in accordance with the channel selection command CSL supplied from the control unit 190 in the mixer after the high frequency band signal is selected by the RF filter. . Of the signals mixed by the mixer in this way, a signal in a predetermined intermediate frequency range is passed through the IF filter and then converted into a digital signal by the ADC. The conversion result is sent to the signal processing unit 130 and the control unit 190.

The signal processing unit 130 receives the intermediate frequency signal IFD sent from the RF processing unit 120. Then, the signal processing unit 130 performs signal processing on the intermediate frequency signal IFD to generate signals DMD _L and DMD _R. The signals DMD _L and DMD _R generated in this way are sent to the analog processing unit 140.

  As will be described later, in the signal processing unit 130, adaptive filtering processing, detection processing, and processing for reproduction are sequentially performed as signal processing. The signal FLD obtained as a result of the adaptive filtering process and the error information ERR obtained in the middle stage of the adaptive filtering process are sent to the control unit 190. Further, in the signal processing unit 130, processing for reproduction is performed in accordance with the processing control CNT sent from the control unit 190.

  Details of the configuration of the signal processing unit 130 will be described later.

The analog processing unit 140 receives the signals DMD _L and DMD _R sent from the signal processing unit 130. Then, the analog processing unit 140 generates output audio signals AOS _L and AOS _R under the control of the control unit 190 and sends them to the speaker units 160 _L and 160 _R. In the present embodiment, the analog processing unit 140 includes a DA (Digital to Analogue) converter, a volume controller, and a power amplifier.

In the analog processing unit 140, the DA converter converts each of the signals DMD _L and DMD _R sent from the signal processing unit 130 into analog signals. Each of the analog signals is subjected to volume adjustment processing in a volume adjustment unit according to a volume adjustment command VLC sent from the control unit 190. Each of the signals subjected to the volume adjustment processing is power amplified by the power amplification unit. The result of this power amplification is sent to the speaker units 160 _L and 160 _R as output audio signals AOS _L and AOS _R.

The speaker unit 160 _L receives the output audio signal AOS _L sent from the analog processing unit 140. Then, the speaker unit 160 _L reproduces and outputs sound according to the output sound signal AOS _L.

The speaker unit 160 _R receives the output audio signal AOS _R sent from the analog processing unit 140. Then, the speaker unit 160 _R reproduces and outputs sound in accordance with the output sound signal AOS _R.

  The input unit 170 is configured by a key unit provided in the main body of the broadcast receiving device 100 or a remote input device including the key unit. Here, as a key part provided in the main body, a touch panel provided in a display unit (not shown) can be used. Moreover, it can replace with the structure which has a key part, and the structure which inputs voice can also be employ | adopted. An input result to the input unit 170 is sent to the control unit 190 as input data IPD.

  The control unit 190 analyzes the input data IPD sent from the input unit 170. When the content of the input data IPD is a channel selection designation including a physical channel, the control unit 190 generates a channel selection command CSL corresponding to the designated physical channel and sends it to the RF processing unit 120. send. If the content of the input data IPD is volume adjustment designation, the control unit 190 generates a volume adjustment command VLC corresponding to the volume adjustment designation and sends it to the analog processing unit 140.

  The control unit 190 also receives the intermediate frequency signal IFD sent from the RF processing unit 120 and the signal FLD and error information ERR sent from the signal processing unit 130. Then, the control unit 190 generates a processing control CNT for controlling the processing for reproduction in the signal processing unit 130 based on the intermediate frequency signal IFD, the signal FLD, and the error information ERR. The processing control CNT generated in this way is sent to the signal processing unit 130.

  Details of the configuration of the control unit 190 will be described later.

<Configuration of Signal Processing Unit 130>
Next, the configuration of the signal processing unit 130 described above will be described.

  As shown in FIG. 2, the signal processing unit 130 includes a noise reduction filter unit 131. Further, the signal processing unit 130 includes a detection unit 132 and a processing unit 133.

  The noise reduction filter unit 131 receives the intermediate frequency signal IFD sent from the RF processing unit 120. Then, the noise reduction filter unit 131 performs an adaptive filtering process for noise reduction using an adaptive algorithm.

  The noise reduction filter unit 131 sends the filtered signal to the detection unit 132 and the control unit 190 as a signal FLD. In addition, the noise reduction filter unit 131 sends error information ERR obtained in the middle of the adaptive filtering process to the control unit 190.

  The details of the configuration of the noise reduction filter unit 131 will be described later.

  The detection unit 132 receives the signal FLD sent from the noise reduction filter unit 131. Then, the detector 132 detects the signal FLD to generate a composite signal DTD (hereinafter referred to as “signal DTD”). The signal DTD generated in this way is sent to the processing unit 133.

The processing unit 133 receives the signal DTD sent from the detection unit 132. Then, the processing unit 133 performs processing for reproduction on the signal DTD in accordance with the processing control CNT sent from the control unit 190, and generates signals DMD _L and DMD _R. The signals DMD _L and DMD _R generated in this way are sent to the analog processing unit 140.

  Details of the configuration of the processing unit 133 will be described later.

<< Configuration of Noise Reduction Filter 131>
Next, the configuration of the noise reduction filter unit 131 described above will be described.

  As illustrated in FIG. 3, the noise reduction filter unit 131 includes an automatic gain control (AGC) unit 210 and a digital filter unit 220. In addition, the noise reduction filter unit 131 includes an adaptive control unit 230.

  The AGC unit 210 receives the intermediate frequency signal IFD sent from the RF processing unit 120. The AGC unit 210 appropriately amplifies the intermediate frequency signal IFD to generate a signal GCD in the intermediate frequency band having a stable amplitude regardless of the signal level of the intermediate frequency signal IFD. The signal GCD generated in this way is sent to the digital filter unit 220 and the adaptive control unit 230.

  In the present embodiment, the digital filter unit 220 is configured as an FIR (Finite Impulse Response) filter. The digital filter unit 220 receives the signal GCD sent from the AGC unit 210. Then, the digital filter unit 220 performs a filtering operation according to the coefficient designation CEF sent from the adaptive control unit 230, and generates a signal FLD. The signal FLD generated in this way is sent to the detection unit 132, the adaptive control unit 230, and the control unit 190.

  The configuration of the digital filter unit 220 will be described later.

  The adaptive control unit 230 receives the signal FLD sent from the digital filter unit 220 and the signal GCD sent from the AGC unit 210. Then, the adaptive control unit 230 generates a coefficient designation CEF based on these signals FLD and GCD. The coefficient designation CEF generated in this way is sent to the digital filter unit 220. Further, the adaptive control unit 230 sends the error information ERR calculated in the middle of generating the coefficient designation CEF to the control unit 190.

  Note that the configuration of the adaptive control unit 230 will be described later.

(Configuration of digital filter unit 220)
Next, the configuration of the digital filter unit 220 described above will be described.

As shown in FIG. 4, the digital filter unit 220 includes (M−1) delay units 221 _{1 to} 221 _M−1 and M coefficient multipliers 222 _{0 to} 222 _M−1 . . In addition, the digital filter unit 220 includes an adder 223.

Each of the delay devices 221 _j (j = 1 to M−1) delays the input signal X _j−1 (T) by a unit delay time τ and outputs it as a signal X _j (T + τ). Here, the signal X ₀ (T) is the signal GCD sent from the AGC unit 210. As a result, the relationship between the signal X _j (T) and the signal X ₀ (T) is expressed by the following equation (1).
X _j (T) = X ₀ (T−j · τ) (1)

In the present embodiment, each of the delay units 221 _j samples the signal X _j−1 (T) in synchronization with a reference clock (not shown) whose period is a unit delay time τ, and the signal X _j (T + τ). Output as. For this reason, during the unit delay time τ, the sampling result is held in the delay unit 221 _j and is output. Here, the unit delay time τ is ¼ of the signal period of the signal X ₀ (T).

The signal X _j (T) generated by the delay unit 221 _j is sent to the coefficient multiplier 222 _j . A signal X ₀ (T) is sent to the coefficient multiplier 222 ₀ .

Each of the coefficient multipliers 222 _m (m = 0 to M−1) receives the signal X _m (T) and the tap coefficient K _m (T) in the coefficient designation CEF sent from the adaptive control unit 230. . The coefficient multiplier 222 _m multiplies the signal X _m (T) by the tap coefficient K _m (T). The result of this multiplication is sent to the adder 223.

The adder 223 performs multiplication results [X ₀ (T) · K ₀ (T)] to [X _M-1 (T) · K _M-1 (T) by the coefficient multipliers 222 _{0 to} 222 _M−1. ]. Then, the adder 223 calculates the signal Y (T) by the following equation (2).
Y (T) = X ₀ (T) · K ₀ (T) +... + X _M-1 (T) · K _M-1 (T) (2)

  The signal Y (T) calculated in this way is sent to the adaptive control unit 230, the detection unit 132, and the control unit 190 as a signal FLD.

(Configuration of Adaptive Control Unit 230)
Next, the configuration of the adaptive control unit 230 will be described.

As shown in FIG. 5, the adaptive control unit 230 includes square calculation units 231 _X and 231 _Y , delay units 232 _X and 232 _Y , addition units 233 _X and 233 _Y, and a low-pass filter (LPC) unit 234. And a subtracting unit 235. In addition, the adaptive control unit 230 includes an absolute value converting unit 241, an LPC unit 242, an amplitude control unit 243, and an amplitude limiting unit 244. Further, the adaptive control unit 230 includes a coefficient update unit 251.

The square calculation unit 231 _X receives the signal GCD (= X ₀ (T)) sent from the AGC unit 210. Then, the square calculation unit 231 _X calculates the signal | X ₀ (T) | ² . The signal | X ₀ (T) | ² calculated in this way is sent to the delay unit 232 _X and the adder 233 _X.

Delay unit 232 _X described above, the signal sent from the squaring out section _{231 X | X 0 (T)} | 2 to be delayed by the unit delay time tau, and sends to the adder 233 _X. As a result, the adder 233 _X receives the signal | X ₀ (T) | ² and the signal | X ₀ (T−τ) | ² at the same time.

The adder 233 _X receives the signal | X ₀ (T) | ² sent from the square calculator 231 _X and the signal | X ₀ (T−τ) | ² sent from the delay unit 232 _X. receive. Then, the adding unit 233 _X calculates an envelope signal X _e (T) indicating an envelope by the following equation (3). The envelope signal X _e (T) calculated in this way is sent to the LPC unit 234.
X _e (T) = | X ₀ (T) | ² + | X ₀ (T−τ) | ² (3)

The LPC unit 234 receives the envelope signal X _e (T) sent from the adding unit 233 _X. Then, the LPC unit 234 generates a DC reference signal V _TH (T) by smoothing the envelope signal X _e (T). The reference signal V _TH (T) thus generated is sent to the subtracting unit 235.

The reason why the DC signal obtained by smoothing the envelope signal X _e (T) is used as the reference signal V _TH (T) is that the amplitude of the FM broadcast signal (and hence the signal GCD (T)) is inherently constant. .

The square calculation unit 231 _Y receives the signal FLD (= Y (T)) sent from the digital filter unit 220. Then, the square calculation unit 231 _Y calculates the signal | Y (T) | ² . The signal | Y (T) | ² calculated in this way is sent to the delay unit 232 _Y and the adder 233 _Y.

Additional delay unit 232 _Y, a signal sent from the squaring out portions _{231 Y | Y (T) |} 2 to be delayed by the unit delay time tau, and sends to the adder 233 _Y. As a result, the adding unit 233 _Y receives the signal | Y (T) | ² and the signal | Y (T−τ) | ² at the same time.

The adder 233 _Y receives the signal | Y (T) | ² sent from the square calculator 231 _Y and the signal | Y (T−τ) | ² sent from the delay unit 232 _Y. Then, the adding unit 233 _Y calculates an envelope signal Y _e (T) indicating an envelope by the following equation (4). The envelope signal Y _e (T) calculated in this way is sent to the subtractor 235.
Y _e (T) = | Y (T) | ² + | Y (T−τ) | ² (4)

The subtractor 235 receives the reference signal V _TH (T) sent from the LPC unit 234 and the envelope signal Y _e (T) sent from the adder 233 _Y. Then, the subtraction unit 235 calculates the error signal e (T) by the following equation (5). The error signal e (T) calculated in this way is sent to the absolute value converting unit 241 and the amplitude limiting unit 244.
e (T) = Y _e (T) −V _TH (T) (5)

  The absolute value converting unit 241 receives the error signal e (T) sent from the subtracting unit 235. Then, the absolute value converting unit 241 converts the error signal e (T) into an absolute value to generate an absolute value signal | e (T) |. The absolute value signal | e (T) | generated in this way is sent to the LPC unit 242 and to the control unit 190 as error information ERR.

  Note that the value of the absolute value signal | e (T) | is a value that accurately reflects the amount of noise such as multipath noise included in the signal FLD at time T.

The LPC unit 242 receives the absolute value signal | e (T) | sent from the absolute value unit 241. Then, the LPC unit 242 generates the smoothed error signal D _ce (T) by smoothing the absolute value signal | e (T) |. The smoothing error signal D _ce (T) generated in this way is sent to the amplitude controller 243.

The amplitude control unit 243 receives the smoothing error signal D _ce (T) sent from the LPC unit 242. Then, the amplitude control unit 243 generates an amplitude control AC (T) based on the smoothing error signal D _ce (T). The amplitude control AC (T) generated in this way is sent to the amplitude limiter 244.

In the present embodiment, the amplitude control unit 243, when the smoothing error signal D _ce (T) does not reach a predetermined value, specifies the amplitude control AC (T that designates “0 dB” as the attenuation rate. ) And sent to the amplitude limiter 244. In addition, when the smoothing error signal D _ce (T) exceeds a predetermined value, the amplitude control unit 243 specifies an amplitude control AC that specifies an attenuation rate proportional to the logarithmic value of the smoothing error signal D _ce (T). (T) is generated and sent to the amplitude limiter 244.

The amplitude limiter 244 receives the error signal e (T) sent from the subtractor 235. Then, the amplitude limiting unit 244 corrects the error signal e (T) according to the amplitude control AC (T) sent from the amplitude control unit 243 to generate a corrected error signal e _cp (T). Thus, the generated correction error signal e _cp (T) is sent to the coefficient updating unit 251.

In the present embodiment, the amplitude limiter 244 is configured as a digital attenuator, and attenuates the error signal e (T) with an attenuation rate specified by the amplitude control AC (T), thereby correcting the correction error signal e _cp. (T) is generated.

The coefficient updating unit 251 includes the signal GCD (= X ₀ (T)) sent from the AGC unit 210, the signal FLD (= Y (T)) sent from the digital filter unit 220, and the amplitude limiting unit 244. The correction error signal e _cp (T) sent from is received. Then, the coefficient updating unit 251 generates a coefficient designation CEF based on these signals Y (T), X ₀ (T), e _cp (T).

When generating the coefficient designation CEF, the coefficient updating unit 251 converges the value of the correction error signal e _cp (T) (and hence the value of the error signal e (T)) to “0” as follows (6) And tap coefficient _Km (T + tau) is computed by (7) Formula.

K _m (T + τ) = K _m (T) −α · e _cp (T) · P _m (T) (6)
here,
P _m (T) = X _m (T) · Y (T) + X _m (T−τ) · Y (T−τ) (7)

  The constant α in equation (6) is a step coefficient that determines the convergence speed of adaptive control, and is determined in advance based on experiments, simulations, experience, and the like from the viewpoint of achieving both stability and speed of adaptive control.

The tap coefficients K ₀ (T + τ) to K _M-1 (T + τ) calculated in this way are sent to the digital filter unit 220 as the coefficient designation CEF. More specifically, the tap coefficient K _m (T + τ) is sent to the coefficient multiplier 222 _m described above. As a result, the tap coefficient supplied to the coefficient multiplier 222 _m is updated.

<< Configuration of Processing Unit 133 >>
Next, the configuration of the processing unit 133 described above will be described.

  As illustrated in FIG. 6, the processing unit 133 includes a normal processing unit 260 and a high-speed high-cut processing unit 270. Here, the normal processing unit 260 includes a mute processing unit 261, a high cut processing unit 262, and a separation processing unit 263.

  Note that the normal processing unit 260 functions as a normal response processing unit. The high-speed high-cut processing unit 270 functions as a high-speed response processing unit.

  The mute processing unit 261 receives the signal DTD sent from the detection unit 132. Then, the mute processing unit 261 performs the mute processing on the signal DTD according to the mute control MTC included in the processing control CNT sent from the control unit 190 and designated the mute rate (attenuation rate), and outputs the signal MTD. Generate. The signal MTD thus generated is sent to the high cut processing unit 262.

  In the present embodiment, the mute processing unit 261 includes a variable digital attenuator.

  The high cut processing unit 262 receives the signal MTD sent from the mute processing unit 261. The high cut processing unit 262 generates a signal NHD by performing high cut processing on the signal MTD in accordance with the normal high cut control NHC that is included in the processing control CNT sent from the control unit 190 and that specifies the high-frequency cutoff rate. To do. The signal NHD generated in this way is sent to the high speed high cut processing unit 270.

  In the present embodiment, the high cut processing unit 262 includes a variable digital filter that can change the cutoff rate of a predetermined high frequency band.

The separation processing unit 263 receives the signal HHD sent from the high speed high cut processing unit 270. The separation processing unit 263 is included in the processing control CNT sent from the control unit 190, and in accordance with the separation control SPC in which the separation degree (separation degree) from the composite signal into the L channel signal and the R channel signal is designated. A separation process is performed on the signal HHD to generate signals DMD _L and DMD _R. The signals DMD _L and DMD _R generated in this way are sent to the analog processing unit 140.

  In the present embodiment, the separation processing unit 263 includes a matrix unit capable of variably adjusting the degree of separation and a de-emphasis unit.

  The high speed high cut processing unit 270 receives the signal NHD sent from the high cut processing unit 262. Then, the high-speed high-cut processing unit 270 performs high-cut processing on the signal NHD according to the high-speed high-cut control HHC included in the machining control CNT sent from the control unit 190 and specified with the high-frequency cutoff rate, and generates the signal HHD. Generate. The signal HHD generated in this way is sent to the separation processing unit 263.

  In the present embodiment, the high-speed high-cut processing unit 270 includes a variable digital filter that can change the cutoff rate of the high-frequency band as in the case of the high-cut processing unit 262 described above.

<Configuration of Control Unit 190>
Next, the configuration of the control unit 190 described above will be described.

  The control unit 190 includes a command processing unit 191 as shown in FIG. The control unit 190 includes a signal level detection unit 192, a noise level detection unit 193, and a normal response control unit 194. Further, the control unit 190 includes a high-speed response control unit 195.

  The command processing unit 191 receives the input data IPD sent from the input unit 170. Then, when the content of the input data IPD is a channel selection designation including a physical channel, the command processing unit 191 generates a channel selection command CSL corresponding to the designated physical channel and sends it to the RF processing unit 120. send. In addition, when the content of the input data IPD is volume adjustment designation, the command processing unit 191 generates a volume adjustment command VLC corresponding to the volume adjustment designation and sends it to the analog processing unit 140.

  The signal level detection unit 192 receives the intermediate frequency signal IFD sent from the RF processing unit 120. Then, the signal level detection unit 192 detects the signal level SLV of the intermediate frequency signal IFD, thereby detecting the electric field strength of the broadcast signal being selected received by the antenna 110. The signal level detected by the signal level detector 192 is sent to the normal response controller 194. That is, the signal level detection unit 192 functions as a first detection unit.

  The noise level detection unit 193 receives the signal FLD sent from the digital filter unit 220. The noise level detecting unit 193 performs AM (Amplitude Modulation) detection on the signal FLD, and then detects the noise level NLV in the signal FLD based on the amplitude of the signal obtained as a result of the AM detection. The noise level NLV detected in this way is sent to the normal response control unit 194. That is, the noise level detection unit 193 functions as a second detection unit.

  The noise level NLV is a value reflecting a noise amount such as multipath noise in the signal FLD that could not be removed by the noise reduction filter unit 131.

  The normal response control unit 194 receives the signal level SLV sent from the signal level detection unit 192 and the noise level NLV sent from the noise level detection unit 193. Then, the normal response control unit 194 generates the above-described mute control MTC, normal high cut control NHC, and separation control SPC based on the signal level SLV and the noise level NLV.

  The mute control MTC, normal high cut control NHC, and separation control SPC generated in this way are sent to the processing unit 133 as part of the processing control CNT. Here, the normal high cut control NHC is also sent to the high-speed response control unit 195.

  Note that the mute control MTC, normal high cut control NHC, and separation control SPC generation processing by the normal response control unit 194 will be described later.

  The high-speed response control unit 195 receives the error information ERR sent from the adaptive control unit 230. Then, the high-speed response control unit 195 generates the above-described high-speed high-cut control HHC based on the error information ERR. Here, the high-speed response control unit 195 generates the high-speed high-cut control HHC while referring to the normal high-cut control NHC. The high-speed high-cut control HHC generated in this way is sent to the processing unit 133 as a part of the processing control CNT.

  Note that the high-speed high-cut control HHC generation processing by the high-speed response control unit 195 will be described later.

[Operation]
Next, the operation of the broadcast receiving apparatus 100 configured as described above will be described mainly focusing on the control of the reproduction processing in the processing unit 133 of the signal processing unit 130.

  As a premise, it is assumed that a channel selection designation has already been input by the user to the input unit 170 and a channel selection command CSL corresponding to the designated physical channel has been sent to the RF processing unit 120. Further, it is assumed that a volume adjustment designation has already been input to the input unit 170 by the user, and a volume adjustment command VLC corresponding to the designated volume adjustment mode has been sent to the analog processing unit 140 (FIG. 1). And FIG. 7).

  In this state, when a broadcast wave is received by the antenna 110, a reception signal RFS is transmitted from the antenna 110 to the RF processing unit 120. Then, the RF processing unit 120 performs channel selection processing for extracting the signal of the physical channel to be selected from the received signal RFS. As a result of this channel selection processing, an intermediate frequency signal IFD having a component in a predetermined intermediate frequency band is sent to the signal processing unit 130 and the control unit 190 (see FIG. 1).

  In the signal processing unit 130, the noise reduction filter unit 131 receives the intermediate frequency signal IFD. The noise reduction filter unit 131 applies an adaptive filtering process for noise reduction to the intermediate frequency signal IFD using an adaptive algorithm to generate a signal FLD. Then, the noise reduction filter unit 131 sends the generated signal FLD to the detection unit 132 and the control unit 190 (see FIG. 2).

In addition, the adaptive control unit 230 in the noise reduction filter unit 131 updates the signal GCD (= X ₀ ) input to the digital filter unit 220 when updating the tap coefficient K _m (m = 0 to M−1) for adaptive filtering processing. (T)) envelope signal X _e (T) is calculated by the above-described equation (3). Subsequently, the envelope signal X _e (T) is smoothed to generate the reference signal V _TH (T) (see FIG. 5).

In addition, in the adaptive control unit 230, the envelope signal Y _e (T) of the output signal FLD (= Y (T)) for the digital filter unit 220 is calculated by the above-described equation (4). Subsequently, the adaptive control unit 230 calculates an error signal e (T) obtained by subtracting the reference signal V _TH (T) from the envelope signal Y _e (T) by the above-described equation (5). Based on the calculated error signal e (T), the tap coefficient K _m is sequentially updated according to the above-described equations (6) and (7), and the update result is supplied to the digital filter unit 220 as the coefficient designation CEF. Sent (see FIG. 5).

  In the adaptive control unit 230, the absolute value of the error signal e (T) is performed by the absolute value converting unit 241 when the coefficient is updated as described above. Then, the result of the absolute value conversion is sent to the control unit 190 as error information ERR (see FIG. 5).

  As described above, the intermediate frequency signal IFD, the signal FLD, and the error information ERR are sent to the control unit 190. The control unit 190 performs normal response machining control and high-speed response machining control based on the intermediate frequency signal IFD, the signal FLD, and the error information ERR.

<Normal response machining control>
The control unit 190 performs normal response machining control based on the intermediate frequency signal IFD and the signal FLD. In the normal response processing control, in the control unit 190, the signal level detection unit 192 detects the signal level SLV of the intermediate frequency signal IFD, and sends the detected signal level SLV to the normal response control unit 194. Further, the noise level detection unit 193 detects the noise level NLV in the signal FLD as described above, and sends the detected noise level NLV to the normal response control unit 194 (see FIG. 7).

  The normal response control unit 194 monitors the signal level SLV and the noise level NLV. The mute control MTC, the normal high cut control NHC, and the separation control SPC described above are generated in response to changes in the signal level SLV and the noise level NLV.

At the time of such generation, the normal response control unit 194, as shown in FIG. 8A, when the signal level SLV is lower than the threshold value TH _S1 , the mute control MTC designating the mute rate corresponding to the signal level SLV. Is generated. Here, the normal response control unit 194 increases the mute rate as the signal level SLV decreases.

Further, the normal response control unit 194, when the signal level SLV is between the threshold value TH _S1 and the threshold value TH _S2 (> TH _S1 ), normal high cut control designating a high-frequency cutoff rate corresponding to the signal level SLV. NHC is produced. Here, the normal response control unit 194 increases the high-frequency cutoff rate as the signal level SLV decreases.

Further, when the signal level SLV is higher than the threshold value TH _S2 , the normal response control unit 194 generates a separation control SPC that specifies the degree of separation corresponding to the signal level SLV. Here, the normal response control unit 194 decreases the degree of separation as the signal level SLV decreases.

Note that the above-described thresholds TH _S1 and TH _S2 are determined in advance based on experiments, simulations, experiences, and the like from the viewpoint of improving the S / N ratio in the reproduced speech.

Furthermore, as shown in FIG. 8B, the normal response control unit 194 generates a separation control SPC designating the degree of separation corresponding to the noise level NLV when the noise level NLV is lower than the threshold value TH _N1. . Here, the normal response control unit 194 increases the degree of separation as the noise level NLV decreases.

Further, the normal response control unit 194, when the noise level NLV is between the threshold value TH _N1 and the threshold value TH _N2 (> TH _N1 ), normal high cut control designating a high-frequency cutoff rate corresponding to the noise level NLV. NHC is produced. Here, the normal response control unit 194 lowers the high-frequency cutoff rate as the noise level NLV decreases.

In addition, when the noise level NLV is higher than the threshold value TH _N2 , the normal response control unit 194 generates a mute control MTC that specifies a mute rate corresponding to the noise level NLV. Here, the normal response control unit 194 lowers the mute rate as the noise level NLV decreases.

  Note that the normal response control unit 194, in processing control corresponding to the noise level NLV, in order to suppress the sensitivity of the control corresponding to the change in the noise level NLV to a low level, the degree of separation determined by the noise level NLV relatively gently. The high-frequency cutoff rate and the mute rate are changed to the control target value.

  The normal response control unit 194 sends the mute control MTC, the normal high cut control NHC, and the separation control SPC generated as described above to the processing unit 133 as a part of the processing control CNT.

<High-speed response machining control>
The control unit 190 performs high-speed response machining control based on the error information ERR. In the high-speed response machining control, in the control unit 190, as shown in FIG. 9, the high-speed response control unit 195 performs high-frequency cutoff with an upper limit of the maximum high-frequency cutoff rate MHT determined according to the value of the error information ERR. A high-speed high-cut control HHC with a specified rate is generated.

In FIG. 9, when the value of the error information ERR is less than the threshold value TH _M1 , the high frequency band is not cut off, and the value of the error information ERR is between the threshold value TH _M1 and the threshold value TH _M2 (> TH _M2 ). In this case, an example is shown in which the maximum high frequency cutoff rate MHT (ERR) increases as the value of the error information ERR increases.

  When generating such high-speed high-cut control HHC, the high-speed response control unit 195 refers to the high-frequency cutoff rate currently specified in the normal high-cut control NHC generated by the normal response control unit 194. Then, as shown in FIG. 10, the high-speed response control unit 195 calculates the high-frequency cutoff rate so as to complement the high-cut processing by the normal high-cut control NHC, and specifies the calculated high-frequency cutoff rate. Produces HHC.

Here, FIG. 10 shows the sum of the high-frequency cutoff amount according to the normal high-cut control NHC and the high-frequency cutoff amount according to the high-speed high-cut control HHC in the decibel unit in the high-cut processing started from time T ₀ . Generates high-speed high-cut control HHC quickly so that the amount corresponds to the maximum high-frequency cutoff amount TAT determined by the maximum high-frequency cutoff rate MHT (ERR) corresponding to the value of error information ERR. An example of complementing the high cut processing by NHC is shown.

  The high-speed response control unit 195 generates the high-speed high-cut control HHC regardless of whether or not the normal response control unit 194 generates the normal high-cut control NHC. If the normal high-cut control NHC is not generated, the high-speed response control unit 195 immediately generates a high-speed high-cut control HHC that specifies the maximum attenuation rate that is determined according to the value of the current error information ERR.

  The high-speed response control unit 195 sends the high-speed high cut control HHC generated as described above to the processing unit 133 as a part of the processing control CNT.

In the processing unit 133 that has received the processing control CNT (mute control MTC, normal high-cut control NHC, high-speed high-cut control HHC, and separation control SPC) generated as described above, the signal DTD sent from the detection unit 132 is received. Then, processing according to the processing control CNT is performed. That is, in the processing unit 133, the mute processing by the mute processing unit 261 according to the mute control MTC, the normal high cut processing by the high cut processing unit 262 according to the normal high cut control NHC, and the high speed high cut processing unit 270 according to the high speed high cut control HHC. And the separation processing by the separation processing unit 263 according to the separation control SPC are sequentially performed. As a result, signals DMD _L and DMD _R are generated, and the generated signals DMD _L and DMD _R are sent to the analog processing unit 140 (see FIG. 6).

In the analog processing unit 140 that receives the signals DMD _L and DMD _R sent from the processing unit 133, signal processing by the DA conversion unit, the volume adjustment unit, and the power amplification unit is sequentially performed, and the output audio signals AOS _L and AOS _R are processed. Is generated. Then, the analog processing unit 140 sends the generated output audio signals AOS _L and AOS _R to the speaker units 160 _L and 160 _R (see FIG. 1). As a result, the speaker units 160 _L and 160 _R reproduce and output sound according to the output sound signals AOS _L and AOS _R.

  As described above, in the present embodiment, the noise reduction filter unit 131 performs the adaptive filtering process on the intermediate frequency signal IFD (input signal) to reduce the signal FLD (noise reduced in the intermediate frequency signal IFD). Output signal). The processing unit 133 performs processing for reproduction on the detection result of the signal FLD. In such processing, the high-speed response control unit 195 in the control unit 190 quickly specifies a high-frequency attenuation rate based on error information between the intermediate frequency signal IFD and the signal FLD reflecting the change in the reception status. A control HHC is generated and sent to the high-speed high-cut processing unit 270 in the processing unit 133. As a result, the high-cut process according to the high-frequency attenuation rate corresponding to the magnitude of the error information ERR is quickly performed.

  Therefore, according to the present embodiment, while adopting a configuration including a noise reduction filter that performs adaptive filtering processing on the intermediate frequency signal, it is possible to perform appropriate reproduction corresponding to a change in reception status such as multipath generation. Processing can be performed with high accuracy.

  In the present embodiment, the normal response control unit 194 in the control unit 190 controls the processing of the conventional technique described above, and the high-speed response control unit 195 supplements the control by the normal response control unit 194. Take control. For this reason, while making use of the advantages of the technology of the conventional example, it is possible to accurately perform a more appropriate processing for reproduction corresponding to a change in reception status.

[Modification of Embodiment]
The present invention is not limited to the above-described embodiment, and various modifications are possible.

  For example, in the above-described embodiment, the high-speed response control unit 195 in the control unit 190 performs only the control of the high cut process, but may further perform control of at least one of the mute process and the separation process.

  In the above embodiment, the present invention is applied to the FM stereo audio broadcast broadcast receiving device. However, the FM monaural audio broadcast receiving device, the FM broadcast receiving device other than the audio broadcast, and the phase modulation (PM) broadcast. The present invention may be applied to a broadcast receiving apparatus.

In the above embodiment, FIG. 9 shows that when the value of the error information ERR is less than the threshold value TH _M1 , the high-frequency cutoff is not performed, and the error information ERR values are the threshold values TH _M1 and TH _M2 (> TH _M1 ), The example in which the maximum high-frequency cutoff rate MHT (ERR) increases as the value of the error information ERR increases. On the other hand, even when the value of the error information ERR is less than the threshold value TH _M1 , the high frequency cutoff is performed at a constant maximum high frequency cutoff rate MHT (ERR), and the error information ERR value is the threshold value TH _M1 and the threshold value. In the case of TH _M2 (> TH _M1 ), the maximum high frequency cutoff rate MHT (ERR) may be decreased as the value of the error information ERR increases.

  In addition, the signal processing unit 130 and the control unit 190 in the above embodiment are configured as a computer as a calculation unit including a central processing unit (CPU), a DSP (Digital Signal Processor), and the like, and prepared in advance. A part or all of the processing in the above embodiment may be executed by executing the program on the computer. This program is recorded on a computer-readable recording medium such as a hard disk, CD-ROM, or DVD, and is read from the recording medium and executed by the computer. The program may be acquired in a form recorded on a portable recording medium such as a CD-ROM or DVD, or may be acquired in a form distributed via a network such as the Internet. Also good.

DESCRIPTION OF SYMBOLS 100 ... Broadcast receiving apparatus 131 ... Noise reduction filter part 132 ... Detection part 133 ... Processing process part 192 ... Signal level detection part (1st detection part)
193 ... Noise level detector (second detector)
194: Normal response control unit (part of control unit)
195 ... High-speed response control unit (part of control unit)
260 ... Normal processing part (normal response processing part)
270 ... High-speed high-cut processing section (high-speed response processing section)

Claims (10)

A broadcast receiving apparatus that receives a broadcast signal and performs signal processing,
A noise reduction filter that uses an intermediate frequency signal obtained by frequency conversion of the broadcast signal as an input signal and performs an adaptive filtering process on the input signal to output an output signal in which noise in the input signal is reduced Part;
A detection unit for detecting the output signal of the noise reduction filter unit;
A processing unit that performs processing for reproduction on the detection result of the detection unit;
A control unit that controls the processing unit based on error information between the input signal and the output signal;
A broadcast receiving apparatus comprising: A first detector for detecting a signal level of the intermediate frequency signal;
A second detection unit that detects a noise level in the output signal of the noise reduction filter unit; and the control unit is further based on a detection result by the first detection unit and a detection result by the second detection unit. Controlling the processing section;
The broadcast receiving apparatus according to claim 1. The processing unit
A normal response processing unit that performs control based on the detection result by the first detection unit and the detection result by the second detection unit;
A high-speed response machining unit that is connected in series with the normal response machining unit and that performs control based on the error information;
The control unit controls the processing by the high-speed response processing unit so that the processing by the normal response processing unit is complemented when an error amount indicated by the error information is a predetermined amount or more.
The broadcast receiving apparatus according to claim 2.   The said error information is information which shows the error amount of the envelope signal of the said output signal, and the time average of the envelope signal of the said input signal, The Claim 1 characterized by the above-mentioned. The broadcast receiving apparatus described.   5. The processing for reproduction includes band reduction processing for reducing a predetermined frequency band component from a detection result by the detection unit, according to claim 1. Broadcast receiving device.   The broadcast receiving apparatus according to claim 1, wherein the reproduction processing includes a mute processing. The broadcast signal is an FM stereo broadcast signal,
The broadcast receiving apparatus according to claim 1, wherein the reproduction processing includes separation processing. A noise reduction filter unit that uses an intermediate frequency signal obtained by frequency conversion of a broadcast signal as an input signal, and performs an adaptive filtering process on the input signal to output an output signal in which noise in the input signal is reduced A signal processing method used in a broadcast receiving apparatus, comprising: a detection unit that detects the output signal of the noise reduction filter unit; and a processing unit that performs a processing for reproduction on a detection result by the detection unit. Because
An acquisition step of acquiring error information between the input signal and the output signal;
A control step of controlling the processing for regeneration by the processing unit based on the acquisition result in the acquisition step;
A signal processing method comprising:   A signal processing program for causing a computer included in a broadcast receiving apparatus that receives a broadcast signal and performs signal processing to execute the signal processing method according to claim 8.   10. A recording medium on which the signal processing program according to claim 9 is recorded so as to be readable by a computer included in a broadcast receiving apparatus that receives a broadcast signal and performs signal processing.

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