JP4293913B2 - Audio device, audio device control method, control program, and recording medium - Google Patents

Description

  The present invention relates to an audio device that can be switched to a parametric equalizer mode or a bass / treble mode, an audio device control method, a control program, and a recording medium.

  2. Description of the Related Art Conventionally, an audio apparatus having a parametric equalizer function for correcting the characteristics of an audio signal in each of a plurality of frequency bands is known (see, for example, Patent Document 1).

In such an audio apparatus, normally, correction data used for correcting the characteristics of the audio signal is temporarily stored in a storage area such as a RAM, and based on the value of the temporarily stored correction data, It is configured to correct the audio signal. In this audio apparatus, correction data is stored in advance, and the stored correction data value is read into the storage area or changed by the user's operation. The stored correction data can be updated with this value.
JP-A-8-310312

  By the way, in the above audio apparatus, in order to improve the acoustic effect, a bass / treble function for correcting characteristics of a predetermined low frequency band and a predetermined high frequency band among a plurality of frequency bands is attached to the function of the parametric equalizer. When the parametric equalizer function and the bus / treble function are configured to be switchable by the user, in order to effectively use the storage area, when the bus / treble function is used, It is desirable that the correction data is read into the storage area.

  However, when such an audio device functions as a bass / treble, the correction data value for the parametric equalizer function stored in the storage area is updated with the correction data value stored in the storage area. If this occurs, the value of the correction data for the bus / treble function will be updated, and when it is desired to function as a parametric equalizer, the value of the updated correction data will be read out. There is a problem that the value of correction data for the treble function is erroneously set.

  SUMMARY OF THE INVENTION An object of the present invention is to solve the above-described problems of the prior art and avoid an erroneous setting of correction data used for correcting an audio signal, a control method for the audio apparatus, and a control program. And providing a recording medium.

  In order to solve the above problem, the present invention provides a parametric equalizer mode for correcting the characteristics of an audio signal in a plurality of frequency bands, or a characteristic of a predetermined low frequency band and a predetermined high frequency band among the plurality of frequency bands. Mode switching means for switching to the bass / treble mode to be corrected, and correction data that can be changed by the user in both the parametric equalizer mode and the bus / treble mode and that is used for correcting the characteristics of the audio signal are temporarily stored. First storage means for storing in memory, second storage means for storing correction data to be read into the first storage means in advance, and correction data stored in the second storage means Rewriting means for updating the value with the value of the correction data stored in the first storage means; / Is characterized in that it comprises in the treble mode and inhibiting means for inhibiting the updating of the value of the correction data stored in said second storage means by said rewriting means.

  In this audio apparatus, the first storage means stores common correction data used for correcting the characteristics of the audio signal in the parametric equalizer mode and the bass / treble mode, and the second storage means The common correction data to be read into one storage means is stored in advance, and the rewriting means stores the common correction data stored in the second storage means in both the parametric equalizer mode and the bus / treble mode. The value may be updated with the value of the common correction data stored in the first storage means.

  In the audio apparatus, when the mode switching unit is switched from the parametric equalizer mode to the bus / treble mode, the first saving unit that saves the value of the correction data in the first storage unit; A second saving means for saving the value of the correction data in the first storage means when the mode switching means is switched from the bus / treble mode to the parametric equalizer mode. When the switching means switches to the bus / treble mode, the correction data value in the first storage means is updated with the correction data value saved in the second saving means, and the mode switching is performed. When switched to the parametric equalizer mode by means, The value of the correction data in the first storage unit may be updated with the first value of the correction data that is saved in the save means.

  The audio apparatus further includes a reading unit that reads correction data from the second storage unit to the first storage unit, and the reading unit is switched to the bus / treble mode by the mode switching unit. The value of the correction data stored in the second storage means is saved in the first save means, and the value of the correction data stored in the first storage means is held as it is. You may do it.

  Also, a parametric equalizer mode for correcting the characteristics of an audio signal in a plurality of frequency bands, or a mode for switching to a bus / treble mode for correcting the characteristics of a predetermined low frequency band and a predetermined high frequency band among the plurality of frequency bands. Correction data that can be changed by the user both in the switching process and in the parametric equalizer mode and the bass / treble mode and that is used for correcting the characteristics of the audio signal is temporarily stored in the first storage means. A first storage process; a second storage process for storing correction data to be read into the first storage means in a second storage means that can be updated in advance; and correction data stored in the second storage means. A rewriting process for updating the value with the value of the correction data stored in the first storage means; It is characterized in that and a prohibition step of prohibiting the updating of the second value of the correction data stored in the storage means according to the rewriting process at Reburu mode.

  In a control program for controlling an audio device by a computer, a parametric equalizer mode for correcting characteristics of an audio signal in a plurality of frequency bands, or a predetermined low frequency band and a predetermined high frequency among the plurality of frequency bands Switching to a bass / treble mode that corrects the characteristics of the band, and correction data that can be changed by the user in both the parametric equalizer mode and the bass / treble mode and that is used to correct the characteristics of the audio signal. Temporary storage in the first storage means, correction data to be read into the first storage means is stored in the second storage means that can be updated in advance, and the correction data stored in the second storage means The value is the value of the correction data stored in the first storage means. New Toe, the bus / in treble mode to prohibit the updating of the value of the correction data stored in said second storage means, it is characterized in.

  A computer-readable recording medium records the control program.

  According to the present invention, it is possible to avoid erroneous setting of correction data used for correcting an audio signal.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the present embodiment, as an aspect of the audio apparatus, an in-vehicle audio apparatus mounted on a vehicle or the like is illustrated. FIG. 1 is a block diagram showing a functional configuration of an in-vehicle audio apparatus 1 according to the present embodiment, and FIG. 2 is a front view showing its appearance.

  First, as shown in FIG. 2, a front panel 1 a is mounted on the front surface of the in-vehicle audio device 1. A CD (Compact Disc) insertion slot 24 is formed above the front panel 1a, and a CD can be inserted from this insertion slot. In addition, a display panel 13a such as a liquid crystal display or an organic EL (Electro Luminescence) display is provided at substantially the center of the front panel 1a. The display panel 13a has an operating state of the in-vehicle audio device 1 and a CD being reproduced. Various information such as a track number, a reproduction music title, and a reception channel such as a radio is displayed.

  On the left side of the display panel 13a, a volume switch 20 which is a rotary operator for adjusting the volume (volume) is disposed. The volume switch 20 has a push-type switch function superimposed thereon. When the volume switch 20 is pressed, the playback sound is muted (MUTE).

  An adjustment switch 21 that is a push-down switch is disposed at the lower left of the volume switch 20, and an operation mode switch 23 that is also a push-down switch is disposed at the upper left of the volume switch 20. ing. The adjustment switch 21 is operated when an adjustment screen for performing various adjustments of the in-vehicle audio device 1 is displayed on the display panel 13a. In particular, in the present embodiment, various settings relating to reproduced sound are performed. Is also performed by operating the adjustment switch 21.

  The operation mode switch 23 is operated when switching the operation mode of the in-vehicle audio device 1.

  On the right side of the display panel 13a, an operation key 22 provided with three first to third operation keys 22a to 22c is disposed. These three first to third operation keys 22a to 22c are seesaw type switches having a vertically long key shape. In the present embodiment, the upper part of the first to third operation keys 22a to 22c, or Each preset function is configured to be executed by pressing the lower part.

  Specifically, when the upper part of the first operation key 22a is pressed, when playing a CD or when the CD autochanger is connected as an external device, it functions as a scan (SCN) key, and when the adjustment screen is displayed, the cursor is moved. Functions as a key to move left (or higher level). On the other hand, when the lower part of the first operation key 22a is pressed, it functions as a key for sequentially switching a plurality of discs in the forward direction when the CD autochanger is connected as an external device, and the cursor is moved downward when the adjustment screen is displayed. Functions as a key to move to (or the next item in the same hierarchy).

  When the upper part of the second operation key 22b is pressed, when a CD is played or when a CD autochanger is connected as an external device, it functions as a repeat playback (RPT) key. When the adjustment screen is displayed, the cursor is moved to the right. Functions as a key to move in the direction (or lower hierarchy). On the other hand, when the lower part of the second operation key 22b is pressed, when the CD autochanger is connected as an external device, it functions as a key for sequentially switching a plurality of discs in the reverse direction. Functions as a key to move upward (or the previous item in the same hierarchy).

  When the upper part of the third operation key 22c is pressed, it functions as a random playback (RDM) key during CD playback or when a CD autochanger is connected as an external device. On the other hand, when the lower part of the third operation key 22c is pressed, a function preset by the user (no assignment in the initial state) is executed.

  Further, a display key 25 for the user to switch display on / off of the display panel 13a is provided at the lower left of the display panel 13a. Here, “display off” refers to a state where not only the display on the display panel 13a is not performed but also the power supply to the driver circuit that drives the display panel 13a is cut off. Therefore, for example, it is possible to turn off the display during CD reproduction, thereby preventing an electric signal for driving the display panel 13a from being mixed into the reproduction signal as noise.

  Furthermore, a display key 25 for the user to switch display on / off on the display unit 13 is arranged on the lower left side of the display unit 13.

  In addition to the above-described components, the front panel 1a of the in-vehicle audio device 1 includes a power on / off / function key, a search up key, a play / pause / input confirmation (ENT) key, a search down key, a band A switch (during radio reception) / leading song move (during CD playback) / lead disc move (during CD changer playback) key is provided.

  The in-vehicle audio apparatus 1 according to the present embodiment is configured to classify the frequency bands of sounds to be reproduced into four ranges, a high range, a middle range, a low range, and a subwoofer, and to reproduce sounds in each frequency band in stereo. As shown in FIG. 1, an analog terminal output unit 8 is provided for outputting each of these frequency band signals (reproduced analog signals) to a speaker (not shown).

  Next, the electrical configuration of the in-vehicle audio device 1 will be described in detail. As shown in FIG. 1, the in-vehicle audio apparatus 1 includes a controller 11 that controls each part of the apparatus. The controller 11 is composed of a microcomputer or the like. The controller 11 is connected to an operation unit 12 including various operation keys and operation switches such as the operation keys 22 and the volume switch 20 described above. Various operations on the operation unit 12 by the user are performed by the controller 11. In response to this input, the controller 11 executes processing. The controller 11 is connected to the display panel 13a and a display unit 13 including a driver circuit (not shown) for driving the display panel 13a. Under the control, various information such as the operation state of the in-vehicle audio device 1, the reproduced music, the reception radio channel, and the like are displayed.

  The in-vehicle audio apparatus 1 also reads a digital signal (for example, a music signal) recorded on a CD and outputs the digital signal to a DSP (Digital Signal Processor) 4 via the digital interface 3. The CD drive 2 is a digital audio source. Built in. The digital interface 3 is connected to the CD drive 2 in a serial signal and connected to the DSP 4 in a parallel signal, and converts the digital signal from the CD drive 2 into a two-channel parallel signal including an L channel and an R channel for stereo reproduction. And output to DSP4.

  The DSP 4 functions as a reproducing means for reproducing the input 2-channel digital signal, and 2 channels (R) for each of the high-range speaker, the middle-range speaker, the low-range speaker, and the subwoofer from the input digital signal. A total of eight digital signals (channel, L channel) are generated, and equalization processing such as filtering and gain setting, alignment (delay time), etc., under the control of the controller 11 for each of these eight channel signals The surround processing is performed and output to the D / A converter (DAC) 5.

  Here, the DSP 4 of the present embodiment includes a parametric equalizer having a plurality of peaking equalizers, and four frequency bands for a high range, a middle range, a low range, and a subwoofer. A filter circuit that adjusts the passband frequency (cutoff frequency), frequency bandwidth (crossover), and gain is provided, and the parameters of the parametric equalizer and the parameters of each filter circuit can be set as the sound field of the reproduced sound. The user can adjust the correction for adjustment.

  The D / A converter 5 converts the digital signals for 8 channels output from the DSP 4 into analog signals and outputs the analog signals to the electronic volume 6. The electronic volume 6 individually adjusts the gains of the eight input analog signals under the control of the controller 11, and outputs them to the analog output terminal unit 8 via the mute circuit 7.

  On the other hand, under the control of the controller 11, the mute circuit 7 puts all eight analog signals into the mute (silence) state or outputs them as they are. That is, mute of all channels is performed by the mute circuit 7, and individual volume adjustment for each channel is performed by the electronic volume 6.

  The in-vehicle audio apparatus 1 includes a tuner 9 as an analog audio source in addition to the digital audio source. The tuner 9 receives broadcast radio waves such as radio broadcasts and outputs an analog signal. The analog signal is input to the DSP 4 via the selector 10. The DSP 4 incorporates an A / D conversion circuit (not shown). When an analog signal is input, the DSP 4 converts the analog signal into a digital signal, and after applying various sound field effects as described above, the D / A converter 5 is output. The selector 10 selects an analog audio source signal to be input to the DSP 4 under the instruction of the controller 11.

  The in-vehicle audio apparatus 1 includes an external device connection terminal 16 and an optical input / output terminal 15 as terminals for transmitting / receiving data to / from an external device.

  FIG. 3 is a block diagram showing the configuration of the controller 11.

  The controller 11 includes a CPU (Central Processing Unit) 30, a RAM (Random Access Memory) 31, an EEPROM (Electrically Erasable and Programmable ROM) 32, and the like, and the operation of the in-vehicle audio device 1 is centralized according to a control program stored in the EEPROM 32. Control.

  The RAM 31 is a memory that temporarily stores a control program, data, and the like read from the EEPROM 32 by the CPU 30. The EEPROM 32 stores various control programs and various data.

  FIG. 4 is a functional block diagram showing the configuration of the DSP 4.

  The DSP 4 (audio signal processing means) inputs a 2-channel digital audio signal (audio signal) consisting of an L channel and an R channel, and divides the frequency axis for each channel into a plurality (in this embodiment, 5 bands). For each divided frequency band, a plurality (five in this embodiment) of L channel equalizer units 40-1 to 40-5 that correct the characteristics of the input audio signal and a plurality (five in this embodiment) are provided. ) R channel equalizer units 41-1 to 41-5. In FIG. 4, the plurality of L channel equalizer units 40-1 to 40-5 are denoted by Lch-EQBAND1 to 5, and the plurality of R channel equalizer units 41-1 to 41-5 are denoted by Rch-EQBAND1 to 5. Show.

  Further, the DSP 4 uses the R and L channel equalizer units 40-1 to 40-5 and 41-1 to 41-5 to correct the L and R channel audio signals for the high range speaker and the middle range speaker. The time alignment is adjusted to generate a total of 8 audio signals of 2 channels each for the low range speaker and the subwoofer.

  Specifically, the high-range L channel will be described. A low-pass filter (HIGH-LPF in FIG. 4) 42-1 and a high-pass filter (HIGH-HPF in FIG. 4) 43-1 are provided. A band-pass filter of a frequency band corresponding to the high range is formed, and a time alignment unit (HIGH-Lch-DELAY in FIG. 4) 44-1 for adjusting time alignment is further provided. The low-pass filter 42-1, the high-pass filter 43-1 and the time alignment unit 44-1 output an L-channel audio signal (digital signal) in the high range to the D / A converter 5.

  Similarly, it includes low-pass filters 42-2 to 42-8, high-pass filters 43-2 to 43-8, and time alignment units 44-2 to 44-8, and R channel audio in a frequency band corresponding to the high range. L, R channel audio signal in the frequency band corresponding to the signal, middle range, L frequency band corresponding to the low range, L, R channel audio signal, and L, R in the frequency band corresponding to the subwoofer range The channel audio signal is output to the D / A converter 5.

  In the present embodiment, the DSP 4 is a parametric equalizer mode (hereinafter referred to as “P.EQ mode”) that functions as a parametric equalizer that corrects the characteristics of an audio signal in a plurality (five) of frequency bands, or a plurality (a P.EQ mode). Of the five frequency bands, any of a bus / treble mode (hereinafter referred to as “BASS / TREB mode”) functioning as a bus / treble that corrects characteristics of a predetermined low frequency band and a predetermined high frequency band. Either one is switched by the controller 11. For example, it can be switched by an operation mode switch 23 shown in FIG.

  More specifically, the L. channel equalizer units 40-1 to 40-5 and the R channel equalizer units 41-1 to 41-5 function as peaking equalizers that can be adjusted by the user to function as parametric equalizers. The EQ mode and the R and L channel equalizer units 40-1 and 41-1 corresponding to a predetermined low frequency band are made to be adjustable by the user, and the R and L channel equalizer units 40- corresponding to a predetermined high frequency band are operated. 3 and 41-3 are functioned so as to be adjustable by the user, and the remaining R and L channel equalizer units 40-2, 40-4, 40-5, 41-2, 41-4, and 41-5 are not functioned (that is, The audio signal is not adjusted) and is switched by the controller 11 to either one of the BASS / TREB mode.

  5 to 7 are explanatory diagrams showing correction data used for correcting the characteristics of the audio signal stored in the RAM 31 and the EEPROM 32 in the controller 11.

  As the correction data, the center frequency f0, the gain G, and the selection used for correcting the audio signal in each of the L and R channel equalizer units 40-1 to 40-5, 41-1 to 41-5 (FIG. 4). Degree Q data, filter characteristic data used for correcting the audio signal in the low-pass filters 42-1 to 42-8 and the high-pass filters 43-1 to 43-8 (FIG. 4), and the time alignment unit 44- 1 to 44-8 includes data relating to a delay time used for correcting an audio signal. The filter characteristic data includes cut-off frequency fcl and attenuation slope sl data used to correct the audio signal in the low-pass filters 42-1 to 42-8 (FIG. 4), and high-pass filters 43-1 to 43-8. The data of the cut-off frequency fch and the attenuation gradient sh used for correcting the audio signal in FIG. 4 and the audio signal are corrected in the low-pass filters 42-1 to 42-8 and the high-pass filters 43-1 to 43-8. There are gain Ga in the passband used for the purpose and phase Ph data indicating the phase correction amount of the audio signal.

  The RAM 31 serves as a first storage means as a center frequency f0, gain G, and selectivity Q as correction data used in the L and R channel equalizer units 40-1 to 40-5 and 41-1 to 41-5 of the DSP 4. EQ current memory 31A (FIG. 5) for temporarily storing the data and a filter as correction data used in the low-pass filters 42-1 to 42-8 and the high-pass filters 43-1 to 43-8 of the DSP 4 X-OVER current memory 31B (FIG. 6) for temporarily storing characteristic data, and delay time data as correction data used in time alignment units 44-1 to 44-8 are temporarily stored. A TIME-A current memory 31C (FIG. 7).

  More specifically, as shown in FIG. 5, the EQ current memory 31A includes an EQ current memory unit 31A- corresponding to each of the L and R channel equalizer units 40-1 to 40-5 and 41-1 to 41-5. 1 to 31A-10, and the EQ current memory units 31A-1 to 31A-10 include corrections used in the L and R channel equalizer units 40-1 to 40-5 and 41-1 to 41-5. Data of the center frequency f0, gain G, and selectivity Q as data for use are temporarily stored.

  Further, as shown in FIG. 6, the X-OVER current memory 31B includes an X-OVER current memory unit corresponding to a band-pass filter including low-pass filters 42-1 to 42-8 and high-pass filters 43-1 to 43-8. 31B-1 to 31B-4, and each X-OVER current memory unit 31B-1 to 31B-4 includes low pass filters 42-1 to 42-8 and high pass filters 43-1 to 43-8. Data of filter characteristics (cut-off frequencies fcl, fch, attenuation gradients sl, sh, gain Ga, and phase Ph) as correction data to be used are temporarily stored.

  As shown in FIG. 7, the TIME-A current memory 31C includes TIME-A current memory units 31C-1 to 31C-8 corresponding to the time alignment units 44-1 to 44-8. -A Current memory units 31C-1 to 31C-8 temporarily store delay time data.

  Further, the RAM 31 has a P.A. In the EQ mode, data of the center frequency f0, gain G, and selectivity Q as correction data used in the L and R channel equalizer units 40-1 to 40-5 and 41-1 to 41-5 of the DSP 4 are saved (stored). P.) as the first evacuation means. EQ temporary memory 31D, center frequency f0, gain G and selection as correction data used in L and R channel equalizer sections 40-1, 40-3, 41-1, and 41-3 of DSP 4 in BASS / TREB mode A BASS / TREB temporary memory 31E is provided as second saving means for saving (storing) data of degree Q.

  Specifically, P.I. As shown in FIG. 5, the EQ temporary memory 31 </ b> D includes the P.P. EQ temporary memory units 31D-1 to 31D-10 are provided. Each P.I. The EQ temporary memory units 31D-1 to 31D-10 include a center frequency f0 and gain G as correction data used in the L and R channel equalizer units 40-1 to 40-5 and 41-1 to 41-5. And data of selectivity Q is saved (stored).

  As shown in FIG. 5, the BASS / TREB temporary memory 31E includes a BASS temporary memory unit 31E-1 corresponding to each of the L and R channel equalizer units 40-1 and 41-1, and each L and R channel equalizer. It has a TREB temporary memory unit 31E-2 corresponding to the units 40-3 and 41-3. Each of the BASS temporary memory unit 31E-1 and the TREB temporary memory unit 31E-2 has correction data used in each of the L and R channel equalizer units 40-1, 41-1, 40-3, and 41-3. Data of the center frequency f0, gain G, and selectivity Q is saved (stored). Here, the correction data saved in the BASS temporary memory unit 31E-1 is used in common by the L and R channel equalizer units 40-1 and 41-1, and the TREB temporary memory unit 31E-2. The correction data to be saved is commonly used by the L and R channel equalizer units 40-3 and 41-3.

  Here, a signal indicating the contents (value of correction data) stored in the EQ current memory 31A, the X-OVER current memory 31B, and the TIME-A current memory 31C in the RAM 31 is output to the DSP 4 under the control of the CPU. The L and R channel equalizer units 40-1 to 40-5, 41-1 to 41-5, the low pass filters 42-1 to 42-8, the high pass filters 43-1 to 43-8, and the times The alignment units 44-1 to 44-8 correct the audio signal based on the value of the correction data input from the RAM 31.

  Further, the contents (values of correction data) stored in the EQ current memory 31A, the X-OVER current memory 31B, and the TIME-A current memory 31C in the RAM 31 are the same as those in the P.P. It can be changed by the user in both the EQ mode and the BASS / TREB mode. For example, the correction stored in the EQ current memory 31A, the X-OVER current memory 31B, and the TIME-A current memory 31C in the RAM 31 by the adjustment switch 21 and the first to third operation keys 22a to 22c shown in FIG. The data value can be changed.

  In the present embodiment, in the initial state after the power is turned on, the EQ current memory 31A, the X-OVER current memory 31B, the TIME-A current memory 31C in the RAM 31 are based on the control program stored in the EEPROM 32. P. The initial value of the correction data is stored in the EQ temporary memory 31D and the BASS / TREB temporary memory 31E, and each initial value is output to the DSP 4.

  The EEPROM 32 serves as the second storage means, the EQ current memory 31A of the RAM 31 or the P.P. The correction data value to be read into the EQ temporary memory 31D is stored in an updatable manner. The EQ memory [0] M1-1 (FIG. 5) and the X-OVER memory [0] M1-2 (FIG. 6) that store the values of correction data to be read into the X-OVER current memory 31B of the RAM 31 in an updatable manner. ) And a TIME-A memory [0] M1-3 (FIG. 7) that stores the value of correction data to be read in the TIME-A current memory 31C of the RAM 31 in an updatable manner.

  In the present embodiment, the EEPROM 32 includes a P.264 file as shown in FIGS. A plurality of preset memories having the same configuration as the preset memory including the EQ memory [0] M1-1, the X-OVER memory [0] M1-2, and the TIME-A memory [0] M1-3 are provided. . For example, in the present embodiment, there are three preset memories, which are referred to as “MEMORY1”, “MEMORY2”, and “MEMORY3”, respectively. That is, the preset memory “MEMORY1” EQ memory [0] M1-1, X-OVER memory [0] M1-2, and TIME-A memory [0] M1-3, preset memory “MEMORY2” EQ memory [1] M2-1, X-OVER memory [1] M2-2, and TIME-A memory [1] M2-3, preset memory “MEMORY3” An EQ memory [2] M3-1, an X-OVER memory [2] M3-2, and a TIME-A memory [2] M3-3 are provided.

  That is, as shown in FIG. In addition to EQ memory [0] M1-1, P.E. P.D. having the same configuration as the EQ memory [0] M1-1. EQ memory [1] M2-1 and P.E. An EQ memory [2] M3-1 is provided. In addition to the X-OVER memory [0] M1-2, the EEPROM 32 includes an X-OVER memory [2] M2 having the same configuration as the X-OVER memory [0] M1-2, as shown in FIG. -2 and X-OVER memory [3] M3-2. As shown in FIG. 7, the EEPROM 32 includes a TIME-A memory [1] M2-3 and a TIME-A memory [2] M3-3 having the same configuration as the TIME-A memory [0] M1-3. Is provided.

  A plurality of P.P. EQ memory [0] M1-1, P.I. EQ memory [1] M2-1 and P.E. EQ memory [2] The EQ memory group 32A is configured, and a plurality of X-OVER memory [0] M1-2, X-OVER memory [1] M2-2, and X-OVER memory [2] M3-2 include an X-OVER memory group 32B. A plurality of TIME-A memories [0] M1-3, TIME-A memories [1] M2-3, and TIME-A memories [2] M3-3 constitute a TIME-A memory group 32C.

  P. As shown in FIG. 5, each of the EQ current memory units 31A-1 to 31A-10 or each of the P.E. The correction data to be read into the EQ temporary memory units 31D-1 to 31D-10 are stored in an updatable manner. EQ memory units 32A-1 to 32A-10 are provided.

  Further, as shown in FIG. 6, the X-OVER memory [0] M1-2 stores the correction data to be read in each X-OVER current memory unit 31B-1 to 31B-4 in an updatable manner. OVER memory units 32B-1 to 32B-4 are provided.

  Further, as shown in FIG. 7, the TIME-A memory [0] M1-3 stores, in an updatable manner, data for correction to be read into the respective TIME-A current memory units 31C-1 to 31C-8. A memory units 32C-1 to 32C-8 are provided.

  In the present embodiment, a switch for selecting any one of a plurality of preset memories “MEMORY1”, “MEMORY2”, and “MEMORY3” and reading the correction data value of the selected preset memory into the RAM 31. It has. For example, the adjustment switch 21 and the first to third operation keys 22a to 22c shown in FIG.

  In the present embodiment, a preset memory in which any one of the plurality of preset memories “MEMORY1”, “MEMORY2”, and “MEMORY3” is selected and the value of the correction data stored in the RAM 31 is selected. There is a switch to write to. For example, the adjustment switch 21 and the first to third operation keys 22a to 22c shown in FIG.

  In the above-described configuration, the user changes the P.I. When switching from the EQ mode to the BASS / TREB mode, and from the BASS / TREB mode to the P.S. A case where the mode is switched to the EQ mode will be described.

  FIG. 8 is a flowchart showing the mode switching process performed by the CPU 30, and FIG. 9 is an explanatory diagram showing the mode switching process executed by the CPU 30.

  First, the CPU 30 causes the user to execute P.I. Whether an operation for switching from the EQ mode to the BASS / TREB mode has been performed, or from the BASS / TREB mode to the P.S. It is determined whether an operation for switching to the EQ mode has been performed (step S1).

  In this step S1, the P.S. When it is determined that the operation for switching to the EQ mode has been performed, that is, when switching from step Sa2 to step Sa1 in FIG. 9, the CPU 30 changes the contents of the EQ current memory 31A (value of correction data) to the BASS / TREB temporary memory 31E. (Step S2 in FIG. 8).

  More specifically, when the BASS / TREB mode is set, the values of the correction data in the EQ current memory units 31A-1 and 31-6 in the EQ current memory 31A are set to be the same, and the EQ current The correction data values of the EQ current memory units 31A-3 and 31-8 in the memory 31A are set to be the same.

  That is, when an operation for changing the correction data value of the EQ current memory unit 31A-1 or 31-6 in the EQ current memory 31A is performed, the CPU 30 corrects the EQ current memory units 31A-1 and 31-6. Change the data value. Similarly, when an operation for changing the correction data value of the EQ current memory unit 31A-3 or 31-8 in the EQ current memory 31A is performed, the CPU 30 stores the EQ current memory units 31A-3 and 31-8. Change the value of the correction data.

  Then, the CPU 30 performs P.P. from the BASS / TREB mode by a user operation. When it is determined that the mode has been switched to the EQ mode, the value of one of the correction data stored in the EQ current memory unit 31A-1 or 31-6 is used as the BASS temporary memory unit 31E- of the BASS / TREB temporary memory 31E. 1 and the value of one of the correction data stored in the EQ current memory unit 31A-3 or 31-8 is saved in the TREB temporary memory unit 31E-2 of the BASS / TREB temporary memory 31E. .

  Further, the CPU 30 performs P.P. The contents (value of correction data) of the EQ temporary memory 31D are copied to the EQ current memory 31A (step S3). In other words, the value of the correction data in the EQ current memory 31A is set to P.I. The data is updated with the value of the correction data saved in the EQ temporary memory 31D.

  More specifically, the CPU 30 sets the correction data values stored in the EQ current memory units 31A-1 to 31A-10 in the EQ current memory 31A to P.P. The P.E. in the EQ temporary memory 31D. The data is updated with the value of the correction data saved in each of the EQ temporary memory units 31D-1 to 31D-10.

  Next, the CPU 30 performs a DSP transfer process for transferring the correction data in the EQ current memory 31A to the DSP 4 (step S4). That is, the CPU 30 transfers the contents of the EQ current memory 31A (correction data values) to the DSP 4. As a result, the P.S. Switch to EQ mode.

  Further, in step S1 in FIG. When it is determined that an operation to switch from the EQ mode to the BASS / TREB mode has been performed, that is, when switching from step Sa1 to step Sa2 in FIG. 9, the CPU 30 changes the contents of the EQ current memory 31A (value of correction data) P. It is saved in the EQ temporary memory 31D (step S5 in FIG. 8).

  More specifically, the values of the correction data stored in the respective EQ current memory units 31A-1 to 31A-10 in the EQ current memory 31A are set as P.31. The P.E. in the EQ temporary memory 31D. Each of the EQ temporary memory units 31D-1 to 31D-10 is saved.

  Further, the CPU 30 copies the contents of the BASS / TREB temporary memory 31E (correction data values) to the EQ current memory 31A (step S6). That is, the correction data value in the EQ current memory 31A is updated with the correction data value saved in the BASS / TREB temporary memory 31E.

  Specifically, the CPU 30 uses the values of the correction data stored in the EQ current memory units 31A-1 and 31-6 of the EQ current memory 31A as the BASS temporary memory unit of the BASS / TREB temporary memory 31E. 31E-1 is updated with the value of the correction data saved, and the value of the correction data stored in each of the EQ current memory units 31A-3 and 31-8 of the EQ current memory 31A is changed to BASS / The data is updated with the value of the correction data saved in the TREB temporary memory unit 31E-2 of the TREB temporary memory 31E.

  Next, the CPU 30 performs a DSP transfer process for transferring the correction data in the EQ current memory 31A to the DSP 4 (step S4). That is, the CPU 30 transfers the contents of the EQ current memory 31A (correction data values) to the DSP 4. As a result, P.I. Switch from EQ mode to BASS / TREB mode.

  As described above, P.I. The EQ current memory 31A is shared in both the EQ mode and the BASS / TREB mode. That is, the EQ current memory 31A includes P.I. P. used only in EQ mode. Stores the value of the correction data dedicated to the EQ mode (EQ dedicated correction data) or the value of the correction data dedicated to the BASS / TREB mode (BASS / TREB dedicated correction data) used only in the BASS / TREB mode Will be. As a result, there is no need to provide a current memory for storing BASS / TREB-specific correction data, the storage area can be used effectively, and control when transferring correction data values to the DSP 4 according to the mode is also possible. It will be easy.

  Next, one of the preset memories “MEMORY1”, “MEMORY2”, and “MEMORY3” in the EEPROM 32 is selected by the user and stored in the RAM 31 in the selected preset memory. The processing operation for writing the value of the correction data being stored will be described.

  Here, the value of the correction data stored in the RAM 31 is written to the EEPROM 32 when the value of the correction data adjusted by the user is stored in the EEPROM 32 or the like.

  FIG. 10 is a flowchart showing the correction process of the correction data to the EEPROM 32 by the CPU 30, and FIGS. 11 and 12 are explanatory diagrams showing the write process by the CPU 30.

  First, the CPU 30 determines that the currently set mode is P.264. It is determined whether the mode is the EQ mode or the BASS / TREB mode (step S11). That is, the P.P. The correction data stored in the EQ memory [i] M1-1, M2-1 and M3-1 (i = 0, 1, 2) is EQ-specific correction data, so it is currently set before being written to the EEPROM 32. Judging the mode that has been.

  In this step S11, P.I. When determining that the EQ mode is set, the CPU 30 changes the contents of the EQ current memory 31A (the value of the correction data) to the P.E. EQ memory [i] A process of writing to M1-1, M2-1, or M3-1 (i = 0, 1, 2) is performed (step S12; rewriting means). That is, the CPU 30 executes the P.P. selected by the user. EQ memory [i] The value of the correction data stored in M1-1, M2-1 or M3-1 (i = 0, 1, 2) is used as the correction data stored in the EQ current memory 31A. Update with value.

  For example, the case where the user performs an operation to update the preset memory “MEMORY1” will be described in detail. As shown in FIG. Each P.E in the EQ memory [0] M1-1. The values of the correction data stored in the EQ memory units 32A-1 to 32A-10 are the values of the correction data stored in the respective EQ current memory units 31A-1 to 31A-10 in the EQ current memory 31A. Update. Note that the same operation is performed when the user performs an operation to update the preset memory “MEMORY2” or the preset memory “MEMORY3”, and thus the description thereof is omitted.

  Next, the CPU 30 stores the contents of the X-OVER current memory 31B (correction data values) in the X-OVER memory [i] M1-2, M2-2, or M3-2 (i = 0, 1, 2). A writing process is performed (step S13; rewriting means). That is, the CPU 30 sets the value of the correction data stored in the X-OVER memory [i] M1-2, M2-2, or M3-2 (i = 0, 1, 2) selected by the user as X -OVER Update with the value of the correction data stored in the current memory 31B.

  For example, a case where the user performs an operation of updating the preset memory “MEMORY1” will be described in detail. As shown in FIG. 11, the CPU 30 selects the X-OVER memory [0] M1- selected by the user. 2 is stored in the X-OVER current memory units 31B-1 to 31B-4 in the X-OVER current memory 31B. It is updated with the correction data value. Note that the same operation is performed when the user performs an operation to update the preset memory “MEMORY2” or the preset memory “MEMORY3”, and thus the description thereof is omitted.

  Next, the CPU 30 stores the contents (value of correction data) of the TIME-A current memory 31C in the TIME-A memory [i] M1-3, M2-3, or M3-3 (i = 0, 1, 2). A writing process is performed (step S14; rewriting means). That is, the CPU 30 uses the value of the correction data stored in the TIME-A memory [i] M1-3, M2-3, or M3-3 (i = 0, 1, 2) selected by the user as the TIME. -A Update with the value of the correction data stored in the current memory 31C.

  For example, the case where the user performs an operation to update the preset memory “MEMORY1” will be described in detail. As shown in FIG. 11, the CPU 30 selects the TIME-A memory [0] M1- selected by the user. 3 is stored in each TIME-A current memory unit 31C-1 to 31C-8 in the TIME-A current memory 31C. It is updated with the correction data value. Note that the same operation is performed when the user performs an operation to update the preset memory “MEMORY2” or the preset memory “MEMORY3”, and thus the description thereof is omitted.

  If it is determined in step S11 that the BASS / TREB mode is set, the CPU 30 skips step S12 and proceeds to the process of step S13. Specifically, as shown in FIG. 12, the CPU 30 sets the P.P. of the EEPROM 32 in the BASS / TREB mode. EQ memory [i] Update of the value of correction data stored in M1-1, M2-1 or M3-1 (i = 0, 1, 2) is prohibited (prohibiting means).

  That is, X-OVER memory [i] M1-2, M2-2 and M3-2, and TIME-A memory [i] M1-3, M2-3, M3-3 (i = 0, 1, 2) The correction data stored in P. Common correction data used for correcting the characteristics of audio signals in the EQ mode and the BASS / TREB mode. The correction data stored in the EQ memory [i] M1-1, M2-1, and M3-1 (i = 0, 1, 2) This is EQ-specific correction data used for correcting the characteristics of the audio signal only in the EQ mode.

  Therefore, P.I. In both the EQ mode and the BASS / TREB mode, the X-OVER memory [i] M1-2, M2-2 and M3-2 of the EEPROM 32 and the TIME-A memory [i] M1-3, M2-3, M3 -3 (i = 0, 1, 2) is the value of the common correction data stored in the X-OVER current memory 31B and the TIME-A current memory 31C of the RAM 31. It is updated with. In the BASS / TREB mode, P.P. The correction data stored in the EQ memory [i] M1-1, M2-1 and M3-1 (i = 0, 1, 2) is the correction data stored in the EQ current memory 31A of the RAM 31. Updating with a value (that is, a value of correction data corresponding to the BASS / TREB mode) is prohibited.

  As a result, in the BASS / TREB mode, P.P. Since it is possible to avoid writing the BASS / TREB-specific correction data in the EQ memory [i] M1-1, M2-1 and M3-1 (i = 0, 1, 2). When the EQ mode is set, Even if the correction data stored in the EQ memory [i] M1-1, M2-1 or M3-1 (i = 0, 1, 2) is read, the value of the correction data in the EQ current memory 31A in the RAM 31 However, since it is not rewritten to the value of the BASS / TREB dedicated correction data, erroneous setting of the correction data can be avoided.

  Next, the user selects any one of the plurality of preset memories “MEMORY1”, “MEMORY2”, and “MEMORY3” in the EEPROM 32, and the value of the correction data is selected from the selected preset memory. A processing operation for reading the data into the RAM 31 will be described. Here, the case where the value of the correction data stored in the EEPROM 32 is read into the RAM 31 is, for example, the case where the correction data stored in the EEPROM 32 is called.

  In other words, the value of the correction data stored in the RAM 31 is set to the initial value when the power is turned on again after the power is turned off. Therefore, the value of the correction data stored in the EEPROM 32 is used. This is because it is necessary to read into the RAM 31.

  FIG. 13 is a flowchart showing a process for reading correction data from the EEPROM 32 by the CPU 30, and FIGS. 14 and 15 are explanatory diagrams showing the read process by the CPU 30.

  First, the CPU 30 determines that the currently set mode is P.264. It is determined whether the mode is the EQ mode or the BASS / TREB mode (step S21).

  In step S21, P.I. If it is determined that the EQ mode is set, the CPU 30 determines that the P.E. EQ memory [i] A process of reading the contents (values of correction data) of M1-1, M2-1 or M3-1 (i = 0, 1, 2) into the EQ current memory 31A is performed (step S22; read) means). That is, the CPU 30 executes the P.P. selected by the user. EQ memory [i] The correction data value stored in M1-1, M2-1 or M3-1 (i = 0, 1, 2) is read into the EQ current memory 31A.

  For example, the case where the user performs an operation of reading the correction data in the preset memory “MEMORY1” into the RAM 31 will be described in detail. As shown in FIG. Each P.E in the EQ memory [0] M1-1. The values of the correction data stored in the EQ memory units 32A-1 to 32A-10 are read into the respective EQ current memory units 31A-1 to 31A-10 in the EQ current memory 31A. Note that the same operation is performed when the user performs an operation of reading the correction data in the preset memory “MEMORY2” or the preset memory “MEMORY3” into the RAM 31, and thus the description thereof is omitted.

  Next, the CPU 30 stores the contents (values of correction data) of the X-OVER memory [i] M1-2, M2-2 or M3-2 (i = 0, 1, 2) into the X-OVER current memory 31B. Is read (step S23; reading means). That is, the CPU 30 sets the value of the correction data stored in the X-OVER memory [i] M1-2, M2-2, or M3-2 (i = 0, 1, 2) selected by the user as X Read into the OVER current memory 31B.

  For example, the case where the user performs an operation of reading the correction data in the preset memory “MEMORY1” into the RAM 31 will be specifically described. As shown in FIG. 14, the CPU 30 selects the X-OVER memory selected by the user. [0] The correction data values stored in the X-OVER memory units 32B-1 to 32B-4 in the M1-2 are used as the X-OVER current memory units 31B-1 to 31B-1 in the X-OVER current memory 31B. Read to 31B-4. Note that the same operation is performed when the user performs an operation of reading the correction data in the preset memory “MEMORY2” or the preset memory “MEMORY3” into the RAM 31, and thus the description thereof is omitted.

  Next, the CPU 30 stores the contents (correction data values) of the TIME-A memory [i] M1-3, M2-3, or M3-3 (i = 0, 1, 2) into the TIME-A current memory 31C. A reading process is performed (step S24; reading means). That is, the CPU 30 uses the value of the correction data stored in the TIME-A memory [i] M1-3, M2-3, or M3-3 (i = 0, 1, 2) selected by the user as the TIME. -A Read into the current memory 31C.

  For example, the case where the user performs an operation of reading the correction data in the preset memory “MEMORY1” into the RAM 31 will be described in detail. As shown in FIG. 14, the CPU 30 selects the TIME-A memory selected by the user. [0] The correction data values stored in the respective TIME-A memory units 32C-1 to 32C-8 in M1-3 are used as the respective TIME-A current memory units 31C-1 to 31C-1 in the TIME-A current memory 31C. Read to 31C-8. Note that the same operation is performed when the user performs an operation of reading the correction data in the preset memory “MEMORY2” or the preset memory “MEMORY3” into the RAM 31, and thus the description thereof is omitted.

  Next, the CPU 30 performs a DSP transfer process for transferring the correction data in the EQ current memory 31A to the DSP 4 (step S25). That is, the CPU 30 transfers the contents of the EQ current memory 31A (correction data values) to the DSP 4.

  Next, the CPU 30 performs a DSP transfer process for transferring the correction data in the X-OVER current memory 31B to the DSP 4 (step S26). That is, the CPU 30 transfers the contents of the X-OVER current memory 31B (correction data value) to the DSP 4.

  Next, the CPU 30 performs a DSP transfer process for transferring the correction data in the TIME-A current memory 31C to the DSP 4 (step S27). That is, the CPU 30 transfers the contents of the TIME-A current memory 31C (correction data values) to the DSP 4.

  If it is determined in step S21 that the BASS / TREB mode is set, the CPU 30 determines that the P.I. EQ memory [i] M1-1, M2-1 or M3-1 (i = 0, 1, 2) contents (value of correction data) While reading into the EQ temporary memory 31D, the value of the correction data in the EQ current memory 31A is held as it is (step S28), and the process proceeds to step S23. That is, the CPU 30 executes the P.P. EQ memory [i] The correction data value stored in M1-1, M2-1, or M3-1 (i = 0, 1, 2) is stored in P.E. The EQ temporary memory 31D is saved and the correction data value in the EQ current memory 31A is held as it is.

  For example, the case where the user performs an operation of reading the correction data in the preset memory “MEMORY1” into the RAM 31 will be described in detail. As shown in FIG. 15, the CPU 30 selects the X-OVER memory selected by the user. [0] The correction data values stored in the M1-2 and TIME-A memory [0] M1-3 are read into the X-OVER current memory 31B and the TIME-A current memory 31C. The correction data value stored in the EQ memory [0] M1-1 is stored in the P.E. The correction data value read into the EQ temporary memory 31D and stored in the EQ current memory 31A is a value corresponding to the BASS / TREB mode, and is retained as it is.

  That is, X-OVER memory [i] M1-2, M2-2 and M3-2, and TIME-A memory [i] M1-3, M2-3, M3-3 (i = 0, 1, 2) The correction data stored in P. Common correction data used for correcting the characteristics of audio signals in the EQ mode and the BASS / TREB mode. The correction data stored in the EQ memory [i] M1-1, M2-1, and M3-1 (i = 0, 1, 2) This is EQ-specific correction data used for correcting the characteristics of the audio signal only in the EQ mode. When the correction data is read into the RAM 31, In both the EQ mode and the BASS / TREB mode, the value of the common correction data is read into the X-OVER current memory 31B and the TIME-A current memory 31C. The value of the correction data read into the EQ temporary memory 31D and stored in the EQ current memory 31A is held as it is as a value corresponding to the BASS / TREB mode.

  Accordingly, it is possible to avoid reading the value of the EQ dedicated correction data into the EQ current memory 31A of the RAM 31 in the BASS / TREB mode, so that erroneous setting of the correction data can be avoided.

  As mentioned above, although this invention was demonstrated based on one Embodiment, this invention is not limited to this.

  For example, in the above-described embodiment, the case where the control program for the in-vehicle audio device is stored in the EEPROM has been described. It can also be configured to read from and install. It is also possible to provide a communication interface, download the control program via a network such as the Internet or a LAN, install and execute the control program.

It is a block diagram which shows the functional structure of the audio apparatus concerning this embodiment. It is a front view which shows the external appearance of an audio apparatus. It is a block diagram which shows the structure of a controller. It is a functional block diagram which shows the structure of DSP. It is explanatory drawing which shows the data for a correction | amendment used for correction | amendment of the characteristic of the audio signal memorize | stored in RAM and EEPROM in a controller. It is explanatory drawing which shows the data for a correction | amendment used for correction | amendment of the characteristic of the audio signal memorize | stored in RAM and EEPROM in a controller. It is explanatory drawing which shows the data for a correction | amendment used for correction | amendment of the characteristic of the audio signal memorize | stored in RAM and EEPROM in a controller. It is a flowchart which shows the mode switching process by CPU. It is explanatory drawing which shows the mode switching process performed by CPU. It is a flowchart which shows the write-in process to the EEPROM for the data for correction | amendment by CPU. It is explanatory drawing which shows the write-in process by CPU. It is explanatory drawing which shows the write-in process by CPU. It is a flowchart which shows the reading process from EEPROM of the data for correction | amendment by CPU. It is explanatory drawing which shows the reading process by CPU. It is explanatory drawing which shows the reading process by CPU.

Explanation of symbols

1 In-vehicle audio system (audio system)
4 DSP
11 controller 30 CPU (mode switching means, rewriting means, prohibiting means, reading means)
31 RAM (first storage means, first saving means, second saving means)
32 EEPROM (second storage means)

Claims (7)

Mode switching means for switching to a parametric equalizer mode for correcting characteristics of an audio signal in a plurality of frequency bands, or a bus / treble mode for correcting characteristics of a predetermined low frequency band and a predetermined high frequency band among the plurality of frequency bands When,
First storage means that can be changed by a user in both the parametric equalizer mode and the bass / treble mode, and that temporarily stores correction data used for correcting the characteristics of the audio signal;
Second storage means for preliminarily storing correction data to be read into the first storage means;
Rewriting means for updating the value of the correction data stored in the second storage means with the value of the correction data stored in the first storage means;
Prohibiting means for prohibiting updating of the value of the correction data stored in the second storage means by the rewriting means in the bus / treble mode;
An audio device comprising: The audio device according to claim 1.
The first storage means stores common correction data used for correcting the characteristics of the audio signal in the parametric equalizer mode and the bass / treble mode,
The second storage means stores in advance common correction data to be read into the first storage means,
In the parametric equalizer mode and the bus / treble mode, the rewriting means uses the value of the common correction data stored in the second storage means for the common correction data stored in the first storage means. An audio device that is updated with a data value. The audio device according to claim 2, wherein
A first saving means for saving the value of the correction data in the first storage means when the mode switching means is switched from the parametric equalizer mode to the bus / treble mode;
A second saving means for saving the value of the correction data in the first storage means when the mode switching means is switched from the bus / treble mode to the parametric equalizer mode;
When the mode switching means switches to the bus / treble mode, the correction data value in the first storage means is updated with the correction data value saved in the second saving means,
When the mode switching means switches to the parametric equalizer mode, the correction data value in the first storage means is updated with the correction data value saved in the first saving means. An audio device. The audio device according to claim 3.
Read means for reading correction data from the second storage means into the first storage means,
When the mode switching unit is switched to the bus / treble mode, the reading unit causes the first saving unit to save the value of the correction data stored in the second storage unit. The audio device is characterized in that the value of the correction data stored in the first storage means is held as it is. A parametric equalizer mode for correcting the characteristics of an audio signal in a plurality of frequency bands, or a mode switching process for switching to a bass / treble mode for correcting the characteristics of a predetermined low frequency band and a predetermined high frequency band among the plurality of frequency bands When,
A first storage process in which correction data that can be changed by a user in both the parametric equalizer mode and the bass / treble mode and is used for correcting the characteristics of the audio signal is temporarily stored in the first storage means. When,
A second storage step of storing correction data to be read into the first storage means in a second storage means that can be updated in advance;
A rewriting process for updating the value of the correction data stored in the second storage means with the value of the correction data stored in the first storage means;
A prohibition process for prohibiting updating of the value of the correction data stored in the second storage means by the rewriting process in the bus / treble mode;
A method for controlling an audio device comprising: In a control program for controlling an audio device by a computer,
A parametric equalizer mode that corrects the characteristics of an audio signal in a plurality of frequency bands, or a bus / treble mode that corrects characteristics of a predetermined low frequency band and a predetermined high frequency band among the plurality of frequency bands;
Correction data that can be changed by the user in both the parametric equalizer mode and the bass / treble mode and that is used for correcting the characteristics of the audio signal is temporarily stored in the first storage means,
Correction data to be read into the first storage means is stored in a second storage means that can be updated in advance,
Updating the value of the correction data stored in the second storage means with the value of the correction data stored in the first storage means;
Prohibiting updating of the value of the correction data stored in the second storage means in the bus / treble mode;
A control program characterized by that.   A computer-readable recording medium on which the control program according to claim 6 is recorded.

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