JP3908434B2 - Information equipment with speakers - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to an information device having a self-diagnosis function, and more particularly, to an information device including a speaker that automatically detects whether or not the speaker is connected to an amplifier.
[0002]
[Prior art]
A technique for determining whether or not a connection between devices is reliably established is employed in many fields. For example, in a navigation system, a self-diagnosis function for determining whether a GPS antenna, a beacon, a gyro unit or the like is connected to the system main body and whether a vehicle speed pulse is input to the system main body is standardly installed. .
[0003]
[Problems to be solved by the invention]
In in-vehicle equipment, especially when judging whether the amplifier and the speaker are securely connected, it is necessary for the user to actually emit sound from each speaker and confirm it. If the speakers are arranged on the left and right sides, it is very difficult to determine which speaker is not producing sound, that is, which speaker is not connected to the amplifier. In addition, when performing an operation and confirming that sound is output from each speaker, it takes time for the work.
[0004]
SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and an object of the present invention is to provide information including a speaker that allows the device itself to self-diagnose whether or not the amplifier and the speaker are connected with a simple configuration. To provide equipment.
[0005]
[Means for Solving the Problems]
In order to solve the above problems, an information device including a speaker according to the invention described in claim 1 includes an amplifier, a speaker connected to the amplifier, input means for inputting a predetermined inspection signal to the amplifier, and input of an inspection signal. Connection determining means for determining whether or not the speaker is connected to the amplifier based on the signal to be inspected generated due to the above.
[0006]
An information device including the speaker according to the second aspect of the present invention is an information device including the speaker according to the first aspect, wherein the input means is connected to a plurality of speakers connected to the amplifier. The inspection signals are sequentially input.
[0007]
An information device including the speaker according to claim 3 is the information device including the speaker according to claim 1, wherein the inspection signal is a frequency component outside the human audible frequency band, or It consists of frequency components close to the audible frequency outside the human audible frequency band.
[0008]
According to a fourth aspect of the present invention, there is provided an information device comprising the speaker according to the first aspect, wherein the signal to be inspected is extracted from a power line input to the amplifier. Configure as follows.
[0009]
An information device including the speaker according to the invention described in claim 5 is an information device including the speaker according to claim 4, wherein the signal to be inspected is a ripple component, It is characterized in that the signal level for the ripple is detected.
[0010]
An information device including a speaker according to the invention of claim 6 includes an amplifier mounted on the moving body and a speaker connected to the amplifier, and inputs a predetermined inspection signal to the amplifier when the moving body starts. And input connection means for determining whether or not the speaker is connected to the amplifier based on the signal to be inspected generated due to the input of the inspection signal.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
With reference to FIG. 1, a configuration of an information device 100 including a speaker according to the first embodiment of the present invention will be described below. FIG. 1 is a block diagram when the information device 100 is used as a vehicle-mounted device that is a moving body.
The information device 100 includes, for example, four speakers FLS, FRS, RLS, and RRS arranged on the front left and right and rear left and right, four power ICs 10a to 10d that drive the four speakers FLS, FRS, RLS, and RRS, Connected to the ripple terminals 13a to 13d of the power ICs 10a to 10d, four extraction circuits 20a to 20d for extracting ripple components (signals to be inspected later), and signals (described later) to the input terminals 14a to 14d of the power ICs 10a to 10d. Whether or not the speakers FLS, FRS, RLS, and RRS are connected to the amplifiers 12a to 12d based on the input switching circuit 22 as input means for inputting the inspection signal) and the output voltages of the extraction circuits 20a to 20d. The microcomputer 23 which is a connection determination means for determining whether or not the operation program of the microcomputer 23 is And the stored ROM 24, a display unit 25 for displaying a message or the like, is constituted by a battery 26 and a power supply circuit 27.
[0012]
The four power ICs 10a to 10d are ICs of the same circuit in which electronic volumes 11a to 11d and power amplification amplifiers 12a to 12d are incorporated, respectively, and ripple terminals 13a to 13d are provided. The electronic volumes 11a to 11d of the power ICs 10a to 10d are individually controlled by the microcomputer 23. The four power ICs 10 a to 10 d are supplied with power from the battery 26 via the power supply circuit 27 from individually provided power terminals 18 a to 18 d.
[0013]
In addition, the extraction circuits 20a to 20d connected to the ripple terminals 13a to 13d are configured by the same circuit as described later, and the output voltage is supplied to the microcomputer 23.
[0014]
When the information device 100 performs self-diagnosis as to whether or not the speakers FLS, FRS, RLS, and RRS are connected to the amplifiers 12a to 12d, they are inspected as signals to be input to the input terminals 14a to 14d of the ICs 10a to 10d. The signal is used. This inspection signal is a frequency (20 to 50 kHz) outside the human audible frequency band so that the sound output from the speaker FLS cannot be heard by the user during self-diagnosis, for example, a rectangular wave signal of 30 kHz. Thus, an oscillation circuit is configured in the microcomputer 23 and generated. The reason why the rectangular wave is used is that it can be easily generated by the microcomputer 23. Even if a sine wave is used as the inspection signal, the same effect described later can be obtained. Further, the signal to be inspected indicates a ripple component output to each of the ripple terminals 13a to 13d due to the inspection signal input to the power ICs 10a to 10d.
[0015]
The information apparatus 100 extracts the signals to be inspected generated (leakage) at the ripple terminals 13a to 13d of the power ICs 10a to 10d by the extraction circuits 20a to 20d, and the amplifiers 12a to 12d with the output voltages of the extraction circuits 20a to 20d. Whether the speakers FLS, FRS, RLS, and RRS are connected to 12d is self-diagnosed. Therefore, these operations will be described in detail with reference to FIGS. FIG. 2 extracts the main circuit configuration of the power IC 10a that drives the front left speaker FLS, the battery 26, and the power circuit 27 out of the four power ICs 10a to 10d that constitute the information device 100 shown in FIG. FIG. 3 is for explaining the operation of the extraction circuit 20a. In addition to FIG. 2, the input switching circuit 22 for switching the inspection signal supplied from the microcomputer 23 and the extraction circuit 20a for extracting the signal to be inspected are shown. And showed.
[0016]
As shown in FIG. 2, the power IC 10 a is supplied with power from the battery 26 via the power circuit 27. When the key switch KSW of the power supply circuit 27 is turned on, the power IC 10a supplies the Vcc voltage, which is the power supply voltage, to the electronic volume 11a, the amplifier 12a, and the like. The amplifier 12a has a normal signal input terminal IN and a reference voltage terminal REF, and a signal from the electronic volume 11a is supplied to the signal input terminal IN. The reference voltage terminal REF is supplied with a voltage obtained by resistance-dividing the Vcc voltage and is connected to the ripple terminal 13a. The ripple terminal 13a of the power IC 10a is provided for connecting a smoothing capacitor Cr that removes the ripple of the power supply circuit 27 because it is necessary to supply a reference DC voltage to the reference voltage terminal REF.
[0017]
The power IC 10a supplies a signal input from the input terminal 14a to the amplifier 12a via the electronic volume 11a, and drives the speaker FLS connected to the amplifier 12a. The amplifier 12a follows the input signal and supplies drive current through the path of the power supply terminal 18a, the output terminal 16a, the speaker FLS, and the output terminal 17a. When the output signal increases and the drive current of the amplifier 12a increases, the power IC 10a can output a large signal from the speaker FLS by supplying a current corresponding to the drive current of the amplifier 12a from the power supply terminal 18a. Become. If the drive impedance is zero and the output impedance is infinite, the power supply circuit 27 can supply a stable current to the drive current of the power IC 10a, but is connected from the battery 26 with a long wiring material (power supply line). Therefore, the power supply impedance of the power supply line including the battery 26 is increased. In such a case, the Vcc voltage of the power IC 10a varies slightly depending on the drive current of the amplifier 12a.
[0018]
As described above, the ripple terminal 13a of the power IC 10a is a terminal that generates a reference voltage by resistance-dividing the Vcc voltage. However, when the voltage fluctuation occurs in the Vcc voltage, the smoothing capacitor Cr can completely remove it. The ripple component that could not be output. This ripple component is a component resulting from the signal input to the amplifier 12a, and is output with an amplitude corresponding to the magnitude of the drive current. That is, if, for example, 1 kHz is supplied to the amplifier 12a, 1 kHz is output as a smoothed waveform. Further, the ripple component is output when the driving current is large and is small when the driving current is small.
[0019]
Therefore, the ripple component output to the ripple terminal 13a is generated even when a large input signal is supplied to the power IC 10a when the speaker FLR connected to the output terminals 16a and 17a of the power IC 10a is disconnected or disconnected. Since a large drive current does not flow through the speaker FLS, it becomes small. That is, if the signal output to the ripple terminal 13a of the power IC 10a is accurately extracted and the magnitude of the extracted signal level is monitored, it can be determined whether or not the speaker FLR is disconnected or disconnected. it can. Therefore, the information device 100 of the present invention uses the extraction circuit 20a shown in FIG. 3 to accurately extract the signal output to the ripple terminal 13a.
[0020]
As shown in FIG. 3, the extraction circuit 20a includes an amplifier 21, a coupling capacitor C1, a detection diode D, and high frequency filters C2 and R2. The amplifier 21 is connected to the ripple terminal 13, and the extraction circuit 20 The output is connected to the microcomputer 23.
[0021]
In the power IC 10a, when the electronic volume 11a is set to the rated volume position by the microcomputer 23 and the inspection signal of the rated input is supplied to the input terminal 14a, the signal of the rated power is output to the speaker FLS. At this time, a signal to be inspected is output to the ripple terminal 13a of the power IC 10a. When a rated input is supplied to the input terminal 14a of the power IC 10a, the signal level of the rated signal to be inspected output to the ripple terminal 13a is approximately 50 mVP-P.
[0022]
The extraction circuit 20a amplifies the signal to be inspected output from the ripple terminal 13a of the power IC 10a with the amplifier 21, detects the amplitude with the diode D, and then removes the high frequency components with the high frequency filters C2 and R1 to generate the DC voltage. The state is supplied to the microcomputer 23. Since the extraction circuit 20a amplitude-detects the signal to be inspected at the ripple terminal 13a, a high DC voltage is output if the signal level of the signal to be inspected is large, and a low DC voltage is output if the signal level of the signal to be inspected is small. .
[0023]
For example, when the speaker FLS is disconnected or disconnected, even if the rated input is supplied to the input terminal 14a of the power IC 10a as described above, the drive current of the amplifier 12a decreases, so the power IC 10a The signal level of the signal to be inspected output to the ripple terminal 13a also decreases. At this time, the signal level of the signal to be inspected output to the ripple terminal 13a is about 1/3 of the signal level when the rated input is supplied to the input terminal 14a.
[0024]
The microcomputer 23 outputs a DC voltage output from the extraction circuit 20a when a rated input is supplied to the input terminal 14a of the power IC 10a, and a DC voltage output from the extraction circuit 20a when the speaker FLS is disconnected or disconnected. For example, a threshold value is provided for the DC voltage output from the extraction circuit 20a. If the threshold voltage is equal to or greater than the predetermined threshold value, the speaker FLS is normally connected, and the predetermined voltage is set. If it is below the threshold value, it is possible to determine that the speaker FLS is disconnected or the wiring is disconnected.
[0025]
Therefore, the information device 100 monitors the DC voltage output from each of the extraction circuits 20a to 20d, thereby self-diagnosis whether each of the amplifiers 12a to 12d and each of the speakers FLS, FRS, RLS, and RRS are connected. It becomes possible to do.
[0026]
Next, the operation of the information device 100 including the speaker according to the first embodiment of the present invention will be described with reference to operation flowcharts shown in FIGS. The operation flow shown in FIG. 4 is an operation flow diagram of the microcomputer 23 that is backed up even when the key switch KSW is OFF, and is an operation program stored in the ROM 24 in advance. Therefore, this operation program is automatically executed when the information device 100 is started when the key switch KSW is turned ON by the user. This operation flow diagram is a self-diagnostic program for determining whether the four speakers FLS, FRS, RLS, and RRS are disconnected or disconnected. The front left speaker FLS, the front right speaker FRS, and the rear Self-diagnosis is performed in the order of the left speaker RLS and the rear right speaker RRS.
[0027]
First, the microcomputer 23 of the information device 100 including a speaker monitors whether or not the key switch KSW is turned on in step S10. If the key switch KSW is not turned on (NO), the monitoring operation of step S10 is performed. Continue. If it is determined in step S10 that the key switch KSW has been turned on (YES), the microcomputer 23 proceeds to step S11. Next, in step S11, the microcomputer 23 monitors whether or not the amplifier 12 of the power IC 10 is in a stable state. Since the amplifier 12 is supplied with a reference voltage and is supplied with a predetermined idle current, the amplifier 12 enters a stable state. For example, the amplifier 12 monitors the midpoint voltage or waits for a predetermined time to enter the stable state. Judgment can be made. Therefore, when the microcomputer 23 determines that the amplifier 12 is not in a stable state (NO), the monitoring operation in step S11 is continued. If the microcomputer 23 determines that the amplifier 12 is in a stable state (YES), the microcomputer 23 proceeds to step S12.
[0028]
In step S12, the microcomputer 23 supplies an inspection signal to the input switching circuit 22 and switches the input switching circuit 22 to, for example, the power IC 10a for driving the front left speaker FLS, and then proceeds to step S13. Then, in step S13, the microcomputer 23 sets the electronic volume 11a of the power IC 10a to the rated volume position, and then proceeds to step S14. In step S14, the microcomputer 23 checks the output voltage of the extraction circuit 20a connected to the ripple terminal 13a of the power IC 10a. The microcomputer 23 diagnoses whether or not the speaker FLS is normally connected with the output voltage supplied from the extraction circuit 20a, and stores the diagnosis result and the number of the power IC 10 selected in step S12 in a RAM (not shown). Thereafter, the process proceeds to step S15.
[0029]
In step S15, the microcomputer 23 sets a counter for determining whether or not all the diagnostic operations have been completed (n = 3?). The counter is configured to have an initial value (n = 0) when the key switch KSW is turned on, and to increment by one (n = n + 1) every time step S15 is executed. Therefore, the microcomputer 23 can determine whether or not all the diagnostic operations have been completed by monitoring the number of counters (the number of circuits to be self-diagnosis, in this case, four circuits). If it is determined in step S15 that the diagnostic operation has not ended (NO), the microcomputer 23 proceeds to step S12 and repeatedly executes the diagnostic operation after step S12.
[0030]
That is, the microcomputer 23 supplies an inspection signal to the power IC 10b in step S12, sets the electronic volume 11b to the rated volume position in step S13, checks the output voltage of the extraction circuit 20b in step S14, and performs diagnostic operation in step S15. And the same diagnosis operation is performed on the power IC 10c and the power IC 10d, and the four speakers are obtained from the results of the output voltages of the extraction circuits 20a to 20d for the four power ICs 10a to 10d. It is possible to diagnose whether FLS, FRS, RLS, and RRS are normally connected. If the microcomputer 23 determines in step S15 that the diagnostic operation has been completed (YES), the microcomputer 23 proceeds to step S16. In step S15, the microcomputer 23 displays “no abnormality” if no abnormality is found as a result of the above diagnostic operation, and displays “no rear right speaker connected” if an abnormality is recognized, for example. Or, it is notified by voice. Then, a series of diagnostic operations is completed.
[0031]
As described above, when the information device 100 including the speaker according to the first embodiment of the present invention is used as a moving body, the information device 100 is sequentially applied to a plurality of speakers connected to the amplifier at the time of starting. The test signal is input, the signal level of the signal under test generated due to the input of the test signal is extracted, and it can be determined whether the speaker is connected to the amplifier based on the extracted output voltage.
[0032]
Next, the structure of an information device 150 including a speaker according to the second embodiment of the present invention will be described based on the block diagram shown in FIG. In FIG. 5, parts having the same functions as those in the block diagram shown in FIG.
[0033]
The information device 150 including a speaker according to the second embodiment of the present invention has a configuration in which four electronic volumes 11a to 11d and four amplifiers 12a to 12d are built in one power IC 10. In the power IC 10, since the reference voltage terminals of the four amplifiers 12a to 12d are commonly connected inside the power IC 10, the ripple terminal 13 is provided in one place. Therefore, only one extraction circuit 20 is required. As described in the operation flow diagram, the information device 100 including the speaker according to the embodiment of the present invention supplies a test signal to the power IC 10 and extracts a signal to be tested output to the ripple terminal 13 of the power IC 10. The circuit 20a extracts and diagnoses whether or not the speaker is normally connected with the output voltage, and stores the number of the selected power IC 10 in the RAM together with the diagnosis result. Therefore, the signal to be inspected obtained when the inspection signal is supplied is output due to the power IC 10 that has supplied the inspection signal. That is, in the information device 150 including the speaker according to the second embodiment of the present invention, the signal to be inspected output to the ripple terminal 13 of the power IC 10 is output due to the amplifier 12 to which the inspection signal is supplied. Can be judged. Therefore, in the case of one power IC, the self-diagnosis for the four speakers FLS, FRS, RLS, and RRS can be performed only by providing one extraction circuit 20.
[0034]
In addition, although the information apparatus provided with the speaker by embodiment of this invention demonstrated in the example at the time of setting it as in-vehicle apparatus, it is not limited to this, The same effect can be acquired also for home use and business use it can. Further, although four speakers have been described as an example, the number of speakers is not limited.
[0035]
In addition, the information equipment provided with the speaker according to the embodiment of the present invention is configured by providing an input switching circuit as input means for inputting a predetermined inspection signal to the amplifier, but is configured without using such an input switching circuit. Also good. In other words, the microcomputer is configured to simultaneously input inspection signals to the four power ICs, set the electronic volume of the power IC for self-diagnosis to the rated volume position, and return the electronic volume to the minimum volume position after the self-diagnosis is completed. For example, the inspection signal is supplied to only one speaker among the plurality of speakers, and the same diagnosis result as described above can be obtained.
[0036]
Moreover, although it comprised so that a test | inspection signal might be generated with a microcomputer, you may comprise an oscillator with an external circuit. Further, the oscillation frequency is not limited to 20 to 50 kHz, and may be a frequency component outside the human audible frequency band, and may be configured using a low frequency outside the audible frequency band, and further outside the audible frequency band. However, it may be composed of frequency components close to the audible frequency.
[0037]
【The invention's effect】
According to the present invention, an information device equipped with a speaker inputs a frequency outside the audible frequency band to an amplifier as a test signal, and extracts a signal to be inspected generated due to the test signal with a simple configuration extraction circuit. Since it is configured to determine whether or not the speaker is connected to the amplifier based on the level of the signal level output from the extraction circuit, it is possible to perform self-diagnosis without actually listening to the sound.
[Brief description of the drawings]
FIG. 1 is a block diagram of an information device including a speaker according to a first embodiment of the present invention.
FIG. 2 is a diagram used for explaining the operation of an information device including the speaker of the present invention.
FIG. 3 is a diagram used for explaining the operation of an extraction circuit used in an information device including the speaker of the present invention.
FIG. 4 is an operation flow diagram of the information device including the speaker according to the first embodiment of the present invention.
FIG. 5 is a block diagram of an information device including a speaker according to a second embodiment of the present invention.
[Explanation of symbols]
10a-10d ... Power IC
11a to 11d ... electronic volume 12a to 12d ... amplifiers 13a to 13d ... ripple terminals 14a to 14d ... input terminals 20a to 20d ... extraction circuit 22 ... input switching circuit 23 ... Microcomputer 24 ... ROM
25 ... Display unit 26 ... Battery 27 ... Power supply circuit

Claims (5)

An amplifier,
A speaker connected to the amplifier;
Input means for inputting a predetermined inspection signal to the amplifier;
Control determination means for determining whether or not the speaker is connected to the amplifier based on a signal to be inspected generated due to the input of the inspection signal;
Equipped with a,
The information device having a speaker , wherein the signal to be inspected is extracted from a power supply line input to the amplifier .   The information device with a speaker according to claim 1, wherein the input unit sequentially inputs inspection signals to a plurality of speakers connected to the amplifier.   The information device with a speaker according to claim 1, wherein the inspection signal includes a frequency component outside a human audible frequency band or a frequency component outside the human audible frequency band and close to an audible frequency. The inspected signal is a ripple component,
The information device with a speaker according to claim 1 , wherein the connection determination unit detects a signal level corresponding to the ripple. An amplifier mounted on a moving body and a speaker connected to the amplifier,
Input means for inputting a predetermined inspection signal to the amplifier at the time of starting the moving body;
Connection determination means for determining whether or not the speaker is connected to the amplifier based on a signal to be inspected generated due to the input of the inspection signal;
Equipped with a,
The information device having a speaker, wherein the signal to be inspected is extracted from a power supply line input to the amplifier.

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