Abstract:
A digital audio receiver provides an audio signal line of the receiver with a DRS circuit for compressing a dynamic range of audio signals passing through the audio signal line; and the DRS circuit, provides a control section for controlling gains for said audio signals in accordance with dynamic range control (DRC) data sent from broadcasting stations, thus enabling dynamic range control functions without circuit complication.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to a receiver for digital voice broadcasting. 
     2. Description of Related Art 
     Recently, it has been proposed that voice broadcasting should be digitalized, that is, a voice information signal is sent as a digital voice information signal to improve the quality of voice information. In particular, digital voice broadcasting, that is, digital voice broadcasting (DAB) complying with the Eureka 147 standard has already been made to fit for practical use in European areas. 
     The DAB is provided with a function to allow broadcasting stations to control the gain of an audio signal line in a receiver. 
     This function is called DRC (dynamic range control). To implement the DRC, broadcasting stations send control data called DRC data together with the original voice data. That is, a two-byte area called F-PAD is provided at the end of frames of digital voice data, and DRC data, placed therein, is sent. For example, in the case of mode II, since a frame cycle is 24 ms, DRC data is sent every 24 ms. 
     The DRC data is 6 bits in size and the relationship between the DRC data and the gain of an audio signal line is as shown below. 
     
       
         
               
               
               
             
               
               
             
           
               
                   
                   
               
             
             
               
                   
                 DRC data 
                    Gain 
               
             
          
           
               
                   
                     000000:0 dB  (reference gain) 
               
               
                   
                 000001:+0.25 dB 
               
               
                   
                 000010:+0.50 dB 
               
               
                   
                 000011:+0.75 dB 
               
               
                   
                 . . .  ← Incremented every 0.25 dB step in this section 
               
               
                   
                 111111:+15.75 dB 
               
               
                   
                   
               
             
          
         
       
     
     Incremented every 0.25 dB step in this section 111111:+15.75 dB 
     That is, if “000011” is sent as DRC data from a broadcasting station, the gain of an audio signal line is increased by 0.75 dB, so that the level of an audio signal becomes 0.75 dB higher than a user-specified level. 
     Accordingly, a DAB receiver can, by performing DRC processing using a Digital Signal Processor (DSP), offer music broadcasts excellent in dynamics, one of audio effects. Also, even inexpensive DSPs can be expected to offer the same effect as brought about by an effector using an advanced DSP. 
     DRC having the above described functions and effects is effective, for example, when enjoying music in noisy environments such as inside a running car. 
     However, for example, in the case of a running car, DRC intended by a broadcasting station and listener-desired DRC may differ depending on running environments, such as running on a general road or autobahn, car type, and weather (fine or rainy). Also, DRC data may not be contained in a broadcast itself. 
     Accordingly, a DSP for DRC processing, provided in a DAB receiver, may merely make the receiver more costly and provide no significant effects. 
     SUMMARY OF THE INVENTION 
     The present invention intends to solve such a problem. 
     For this reason, the present invention offers a receiver for digital voice broadcasting which provides an audio signal line with a DRS circuit for compressing a dynamic range of audio signals passing through the audio signal line, and in the DRS circuit, controls gains for the audio signals in accordance with DRC data sent from broadcasting stations. 
     Accordingly, DRC processing is performed in the DRS circuit. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a system diagram showing one embodiment of the present invention. 
     FIG. 2 is a system diagram for explaining the present invention. 
     FIG. 3 is a characteristic diagram for explaining the present invention. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Functions called DRS (dynamic range suppression) are available as audio effector functions. The DRS functions compress a dynamic range of audio signals, and the DRS circuit has input-output characteristics shown in FIG. 3, for example. 
     That is, when DRS is set to a minimum (0), input-output characteristics thereof are shown by characteristic Amin and exhibit a transmission line with a gain of 0 dB. However, when DRS is set to a maximum, input-output characteristics thereof are shown by characteristic Amax; when an input level is lower than a defined value −30 dB, an output level becomes 15 dB higher than the input level, and when an input level is higher than −30 dB, an output level is constant to −15 dB. Furthermore, when DRS is set between the maximum and the minimum, input-output characteristics thereof, which are shown by characteristics A 1  to A 5 , become characteristics intermediate between the characteristics Amin and Amax. 
     Accordingly, for example, with the characteristic Amin usually set, by setting an arbitrary characteristic of A 1  to Amax in accordance with increasing levels of ambient noise, users can comfortably enjoy music and other sounds. 
     The present invention, focusing attention on this point, uses the DRS characteristics to obtain DRC functions. Hereinafter, an embodiment of the present invention will be described with reference to FIG.  1 . 
     In FIG. 1, a DAB broadcast wave signal is received by antenna  11 , and the received signal is supplied to a front end circuit  12  configured in super-heterodyne form and converted into an intermediate frequency signal, which is supplied to an A/D converter circuit  13 , resulting in a digital signal. 
     The digital signal is supplied to orthogonal demodulation circuit  14  in which signals of I and Q components of base band are demodulated and supplied to FFT circuit  15  to be subjected to OFDM demodulation. The OFDM-demodulated data is supplied to Viterbi decoder circuit  16  in which it is deinterleaved and subjected to error correction, and a program (channel) is selected and digital audio data of the desired program is selected. 
     The selected data is supplied to audio decoder circuit  17  in which it is subjected to decode processing such as data extension, and audio data of a desired program is fetched from the decoder circuit  17 . The fetched digital audio data is supplied to D/A converter circuit  19  through DRS circuit  18  described later and is subjected to D/A conversion into analog audio signals of left and right channels. These signals are supplied to speakers  22 L and  22 R through amplifiers  21 L and  21 R. 
     Furthermore, with synchronous circuit  31  provided for synchronous control, signals of I and Q components are supplied to the synchronous circuit  31  from the orthogonal demodulation circuit  14  to form a correction signal for frequency synchronization, and the correction signal is supplied to the front end circuit  12  and the Viterbi decoder circuit  16 . Predetermined signals are accessed between microcomputer  32 , provided for system control, and the synchronous circuit  31 , and also among circuits  16  to  18 . 
     The DRS circuit  18 , including a DSP, for example, is provided with DRC functions, and processing contents thereof are as shown in FIG. 2, for example, if represented by discrete circuits. In FIG. 2, DRS functions providing a constant output level are omitted for simplicity. 
     That is, digital audio data D 17  output from the decoder circuit  17  is supplied to variable attenuator circuit  81  to produce digital audio data D 81  of a predetermined level, the data D 81  is supplied to multiplying circuit  82  and multiplied by a predetermined multiplier to produce digital audio data D 82 , and the data D 82  is supplied to the D/A converter circuit  19 . 
     In the microcomputer  32  to which DRS characteristic specification keys are connected via the interface, control signal SDRS changing according to user-specified DRS characteristics is formed, the signal SDRS is supplied to the attenuator circuit  81  as a control signal thereof, and the attenuator circuit  81  causes attenuation by an amount determined by the signal SRDS. 
     Furthermore, data D 82  from the multiplying circuit  82  is supplied to level detection circuit  83  in which data D 83  indicating the average level of data D 82  is fetched, and the data D 83  is supplied to comparison circuit  84 . 
     DRC data DDRC is fetched from the decoder circuit  17  and supplied to the microcomputer  32 , and when GDRS and GDRC are defined as follow: 
     GDRS: Gain increased from a reference gain by DRS processing. That is, an increased value [dB] from the level of the characteristic Amin in the slant portion of FIG. 3 
     GDRC: Gain indicated by DRC data (increased value from a reference gain) [dB], data DSC is formed so that gain GSC satisfies the following relation: 
     
       
         GSC=GDRS+GDRC  (1) 
       
     
     The data DSC is supplied to the comparison circuit  84 , from which comparison output D 84  is fetched that goes High when D 83 &lt;DSC, and Low when D 83 ≧DSC. 
     The output signal D 84  is supplied to up-down counter  85  as a switching control signal for up-count and down-count, and a clock is input to counter  85  as count input. The counter  85  is incremented when D 84  is High, and decremented when Low. A counted value D 85  of the counter  85  is supplied to the multiplying circuit  82  as a multiplier and multiplied by the data D 81 . 
     Accordingly, although a multiplication D 82 =D 81 ×D 85  is performed in the multiplying circuit  82 , the counter  85  is incremented when D 83 &lt;DSC, and decremented when D 83 ≧DSC, so that D 83  converges to DSC, at which time the average level of data D 82  increases by gain GSC indicated by data DSC. That is, loop gains varying in magnitude depending on the data DSC can be obtained by the circuits  82  to  85 . 
     Accordingly, the gain of the DRS circuit  18  is determined by an attenuation amount of the attenuator circuit  81  and the gain of the multiplying circuit  82 , that is, by the signal SDRS and data DSC. 
     When a user specifies, e.g., the characteristic A 2  of FIG. 3 as a DRS characteristic, the DRS circuit  18  is set to the characteristic A 2 . When the gain GDRC of DRC indicated from a broadcast station is larger than the gain of characteristic A 2  (such as characteristic A 3  to Amax), the characteristic A 2  is changed to a characteristic affording the gain GDRC; when smaller than the gain of characteristic Ai, the indicated gain GDRC is ignored. 
     In other words, when a user specifies the characteristic Ai (Amax≧Ai ≧Amin) of FIG. 3 as a DRS characteristic, the DRS circuit  18  is set to the characteristic Ai. When the gain GDRC of DRC indicated from a broadcast station is larger than the gain of characteristic Ai, the characteristic Ai is changed to a characteristic affording the gain GDRC; when smaller than the gain of characteristic Ai, the indicated gain GDRC is ignored. 
     Therefore, according to the DRS circuit  18 , GRC characteristics can be obtained in accordance with user settings, and if a broadcast station specifies a volume level (gain) by DRC data, at least the specified volume level is ensured. Accordingly, according to the DRS circuit  18 , DRS functions and DRC functions can be obtained at the same time by the circuit  18  alone. 
     In this way, according to the above described DRS circuit  18 , since DRC processing is also performed at the same time as DRS processing, even when the level of ambient noise changes greatly, such as inside a running car, DRC characteristics intended by broadcast stations can be obtained. Moreover, since DRC functions are obtained by a DSP for DRS, cost rises can be curbed. 
     In the foregoing, an intermediate frequency signal from the front end circuit  12  is orthogonally demodulated to obtain signals of I and Q components, and these signals are subjected to A/D conversion before being supplied to the FFT circuit  15 . 
     According to the present invention, DRC characteristics intended by broadcast stations can be obtained even when the level of ambient noise changes greatly, such as inside a running car. Moreover, a rise in receiver costs can be curbed.