JP6422786B2 - Offset voltage monitoring apparatus and offset voltage monitoring method - Google Patents

Description

  The present invention relates to an offset voltage monitoring device, an offset voltage monitoring method, an offset voltage monitoring program, and a recording medium on which the offset voltage monitoring program is recorded.

  Conventionally, when a sound is output from a speaker, a signal amplifying apparatus that amplifies an input signal and supplies the amplified output signal to the speaker has been used. For example, an acoustic device disposed in a vehicle includes a signal amplifying device that employs a BTL (Balanced Transformer Less) amplification method, and outputs an output signal to a speaker in the form of a differential signal having a midpoint voltage of a power supply voltage as a reference voltage. The structure to supply is common.

  When the voltage value of the direct current component (direct current (DC) offset voltage value) in the output signal of such a signal amplifying device exceeds the allowable range, the speaker is damaged. In order to avoid such a situation where the speaker is damaged, it is generally performed to detect the DC offset voltage value of the output signal of the signal amplifying apparatus and control the signal output operation of the signal amplifying apparatus.

  As a technique related to the control of the signal output operation of such a signal amplifying device, the detection result of the occurrence of an event (for example, the occurrence of a signal clip) suspected of causing an offset voltage abnormality of the output signal of the signal amplifying device is sampled, Thus, a technique for detecting an offset voltage abnormality has been proposed (see Patent Document 1: hereinafter referred to as “Conventional Example 1”). In the technique of Conventional Example 1, the sample is performed regularly or irregularly, and when the detection result of the occurrence of the event is continuously sampled a predetermined number of times, it is determined that the offset voltage is abnormal. It has become.

  Also proposed is a technique for detecting an offset voltage abnormality based on the duration of the state in which the voltage value of the output signal output from the signal amplifier exceeds the threshold value from the reference value side and does not return to the reference value. (See Patent Document 2: hereinafter referred to as “Conventional Example 2”). In the technique of Conventional Example 2, when the duration time reaches a predetermined determination time, it is determined that the offset voltage is abnormal.

Japanese Patent No. 4315836 JP 2014-204296 A

  In the technique of Conventional Example 1 described above, the detection result of the occurrence of an event suspected of an offset voltage abnormality is sampled regularly or irregularly. For this reason, it is necessary to implement a timer function for knowing the timing of the sample.

  In the technique of Conventional Example 2, the time duration of a predetermined state is measured. For this reason, the technique of Conventional Example 2 also requires the implementation of a timer function for measuring time.

  In order to implement such a timer function, in addition to the oscillator, a peripheral circuit that is not very small is required. For this reason, when the techniques of the conventional examples 1 and 2 are adopted, it is difficult to easily determine the abnormality of the offset voltage.

  In the technique of Conventional Example 2, the threshold value is a fixed value. However, in the case of an acoustic device, for example, it is general that the user can specify the volume corresponding to the output sound signal that is the output signal of the signal amplifying device. When such volume designation is possible, it is considered that an appropriate value of the threshold value for detecting the offset voltage abnormality changes depending on the volume setting value.

  For this reason, a technique capable of appropriately monitoring the offset voltage with a simple configuration is desired. Meeting this requirement is one of the problems to be solved by the present invention.

According to the first aspect of the present invention, detection of a voltage value of an input signal, detection of a magnitude relationship between the voltage value of the input signal and a reference value, and at least one threshold value set on one side with respect to the reference value are provided. A detection unit that detects that the voltage value of the input signal has exceeded; an acquisition unit that acquires a specified value; a detection result by the detection unit, the acquired specified value and the at least one threshold value, An offset determination unit that determines whether an offset voltage of the input signal is abnormal;
An offset voltage monitoring device comprising:

  According to an eighth aspect of the present invention, detection of a voltage value of an input signal, detection of a magnitude relationship between the voltage value of the input signal and a reference value, and at least one threshold set on one side with respect to the reference value are provided. An offset voltage monitoring method used in an offset voltage monitoring apparatus that includes a detection unit that detects that the voltage value of the input signal has exceeded, and that monitors the offset voltage in the input signal, and acquires a specified value A first acquisition step; a second acquisition step for acquiring a detection result by the detection unit; and an input based on the acquisition result in the first acquisition step, the acquisition result in the second acquisition step, and the at least one threshold value. An offset determination step of determining whether or not the offset voltage of the signal is abnormal.

  According to a ninth aspect of the present invention, an offset voltage monitoring apparatus for monitoring an offset voltage in an inputted input signal is caused to execute the offset voltage monitoring method according to the eighth aspect. This is a voltage monitoring program.

  According to a tenth aspect of the invention, the offset voltage monitoring program according to the ninth aspect is recorded so as to be readable by a computer included in the offset voltage monitoring device that monitors the offset voltage in the input signal. Is a recording medium characterized by the above.

It is a block diagram which shows roughly the structure of the offset voltage monitoring apparatus of 1st Embodiment of this invention. It is a figure for demonstrating the structure of the detection part of FIG. It is a figure for demonstrating the structure of the offset determination part of FIG. It is a figure for demonstrating the example of a change of the threshold value accompanying the change of the volume designation | designated value in 1st Embodiment. It is a figure for demonstrating the count operation | movement by the counting part of FIG. 3 when a volume designation | designated value is smaller than a predetermined value. FIG. 4 is a timing chart for explaining the counting operation by the counting unit in FIG. 3 when the volume designation value is equal to or greater than a predetermined value and the offset voltage is normal. FIG. 4 is a timing chart for explaining the counting operation by the counting unit in FIG. 3 when the volume designation value is equal to or greater than a predetermined value and the offset voltage is abnormal. It is a block diagram which shows roughly the structure of the offset voltage monitoring apparatus of 2nd Embodiment of this invention. It is a figure for demonstrating the structure of the detection part of FIG. It is a figure for demonstrating the structure of the offset determination part of FIG. It is a figure for demonstrating the structure of the counting part of FIG. It is a figure for demonstrating the example of a change of the threshold value accompanying the change of the volume designation | designated value in 2nd Embodiment. 12 is a timing chart for explaining the counting operation by the counting unit in FIG. 11 when the offset voltage is normal. 12 is a timing chart for explaining the counting operation by the counting unit in FIG. 11 when the offset voltage is abnormal (part 1). 12 is a timing chart for explaining the counting operation by the counting unit in FIG. 11 when the offset voltage is abnormal (part 2).

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In the following description and drawings, the same or equivalent elements are denoted by the same reference numerals, and redundant description is omitted.

[First Embodiment]
First, a first embodiment of the present invention will be described with reference to FIGS.

<Configuration>
FIG. 1 is a block diagram illustrating a schematic configuration of an offset voltage monitoring apparatus 100A according to the first embodiment. As shown in FIG. 1, the offset voltage monitoring apparatus 100A power-amplifies the sound signal IPS sent from the signal source 310 and then supplies the amplified signal to the speaker 340 via the switch elements 330 ₁ and 330 _2. The offset voltage of the output signals S ₁ and S ₂ of (PA) 320 is monitored. Here, examples of the sound signal IPS output from the signal source 310 include an audio signal whose volume is adjusted in an audio device, an audio signal whose volume is adjusted in an audio broadcast receiving device, and the like.

In the first embodiment, the power amplifier 320 employs the BTL method. Therefore, the voltage value of the output signal S ₁ is ideally a reference value V _ST (= V _DD / V) that is (1/2) of the power supply voltage value V _DD (> 0) supplied to the power amplifier 320. The value is symmetrical to the voltage value of the output signal S ₂ with 2) as the center of symmetry. Further, the switch elements 330 ₁ and 330 ₂ are open / close type switch elements, and are in a closed state / open state according to “ON” / “OFF” of the supply control designation OSC sent from the offset voltage monitoring apparatus 100A. Become.

In the first embodiment, the voltage values of the output signals S ₁ and S ₂ are changed within the range of 0 to V _DD .

The offset voltage monitoring device 100A is connected to the volume specifying unit 400. The volume designation unit 400 sends the volume designation value VLS to the offset voltage monitoring apparatus 100A. The volume designation value VLS is a value that designates the difference between the maximum voltage value and the minimum voltage value that the output signals S ₁ and S ₂ of the power amplifier 320 can take. That is, the maximum volume value of the sound output from the speaker 340 is designated by the volume designation value VLS.

  In the first embodiment, the maximum amplitude of the sound signal IPS output from the signal source 310 is determined by the volume designation value VLS sent from the volume designation unit 400.

  Further, the offset voltage monitoring device 100A is connected to the information processing device 500. Then, the offset voltage monitoring device 100A sends an offset voltage abnormality instruction OAB to be described later to the information processing device 500.

As shown in FIG. 1, the offset voltage monitoring apparatus 100A includes input terminals TI ₁ and TI ₂ and a detection unit 110A. The offset voltage monitoring apparatus 100A includes an offset determination unit 120A and output terminals TO ₁ and TO ₂ .

The output signals S ₁ and S ₂ of the power amplifier 320 are input to the input terminals TI ₁ and TI ₂ . These input output signals S ₁ and S ₂ are sent to the detection unit 110A.

The detection unit 110A receives the output signals S ₁ and S ₂ . Then, the detection unit 110A first detects the voltage values VD ₁ and VD ₂ of the output signals S ₁ and S ₂ . Subsequently, the detection unit 110A detects the magnitude relationship between the voltage values VD ₁ and VD ₂ and the reference value V _ST . The detection unit 110A generates a signal CR ₁ to "OFF" and the voltage value VD ₁ is below the reference value V _ST, when the voltage value VD ₁ exceeds the reference value V _ST is "ON". The detection unit 110A generates a signal CR ₂ to "OFF" and the voltage value VD ₂ is less than the reference value V _ST, when the voltage value VD ₂ exceeds the reference value V _ST is "ON". The signals CR ₁ and CR ₂ thus generated are sent to the offset determination unit 120A.

The detection unit 110A detects the magnitude relationship between the voltage values VD ₁ and VD ₂ and one threshold value V _TH0 specified by the offset determination unit 120A in parallel with the generation operation of the signals CR ₁ and CR _2. To do. The detection unit 110A generates a signal OT ₁ to "OFF" and the voltage value VD ₁ is the threshold value V _TH0 below, when the voltage value VD ₁ exceeds the threshold value V _TH0 is "ON". The detection unit 110A generates a signal OT ₂ to "OFF" and the voltage value VD ₂ to the threshold value V _TH0 below, when the voltage value VD ₂ exceeds the threshold value V _TH0 is "ON". That is, the detection unit 110A detects that the threshold value V _TH0 of the output signals S ₁ and S ₂ has been exceeded, and when it has been detected that the threshold value V _TH0 has been exceeded, _sets the signals OT ₁ and OT ₂ to “ON”. It is like that. The signals OT ₁ and OT ₂ generated in this way are sent to the offset determination unit 120A.

  Details of the configuration of the detection unit 110A will be described later.

The offset determination unit 120A receives the volume designation value VLS sent from the volume designation unit 400. Then, the offset determination unit 120A determines a threshold value V _TH0 corresponding to the volume designation value VLS. The threshold value V _TH0 thus determined is sent to the detection unit 110A.

Further, the offset determination unit 120A receives signals CR ₁ , CR ₂ , OT ₁ , OT ₂ sent from the detection unit 110A. Subsequently, the offset determination unit 120A determines, based on the signals CR ₁ , CR ₂ , OT ₁ , OT ₂ , whether or not the offset voltage of at least one of the output signal S ₁ and the output signal S ₂ is abnormal.

The offset determination unit 120A is “ON” when it is determined that the offset voltages of both the output signal S ₁ and the output signal S ₂ are not abnormal, and at least the output signal S ₁ and the output signal S ₂ When it is determined that one of the offset voltages is abnormal, a supply control designation OSC that is “OFF” is generated. The supply control designation OSC generated in this way is sent to the switch elements 330 ₁ and 330 ₂ via the output terminal TO ₁ .

The offset determination unit 120A is “OFF” when it is determined that the offset voltages of both the output signal S ₁ and the output signal S ₂ are not abnormal in parallel with the generation operation of the supply control designation OSC. When it is determined that at least one of the offset voltages of the output signal S ₁ and the output signal S ₂ is abnormal, an offset abnormality instruction OAB that is “ON” is generated. The offset voltage abnormality instruction OAB generated in this way is sent to the information processing apparatus 500 via the output terminal TO ₁ . When the offset abnormality instruction OAB is “ON”, the information processing apparatus 500 presents an offset voltage abnormality to the user through image display, audio output, or the like.

  Details of the configuration of the offset determination unit 120A will be described later.

<< Configuration of Detection Unit 110A >>
Next, the configuration of the detection unit 110A described above will be described.

  The detection unit 110A includes a voltage detection unit 111 as shown in FIG. The detection unit 110A includes a reference value comparison unit 112 and a threshold value super detection unit 113A.

The voltage detector 111 receives the output signals S ₁ and S ₂ sent from the power amplifier 320. The voltage detector 111 detects a voltage value of the output signal S _1. The detection result is sent as a detection voltage value VD ₁ to the reference value comparison unit 112 and the threshold value super detection unit 113A.

In addition, the voltage detector 111 detects the voltage value of the output signal S _{2 in} parallel with the operation of detecting the voltage value of the output signal S ₁ . This detection result is sent as the detection voltage value VD ₂ to the reference value comparison unit 112 and the threshold value super detection unit 113A.

The reference value comparison unit 112 receives the detection voltage values VD ₁ and VD ₂ sent from the voltage detection unit 111. Subsequently, the reference value comparing unit 112 compares the detected voltage value VD ₁ and the reference value V _ST. Reference value comparing unit 112 generates a signal CR ₁ and the detection voltage VD ₁ is equal to or less than the reference value V _ST becomes "OFF" and if the detected voltage value VD ₁ exceeds the reference value V _ST "ON" . The signal CR ₁ generated in this way is sent to the offset determination unit 120A.

In addition, the reference value comparison unit 112 compares the detected voltage value VD ₂ with the reference value V _{ST in} parallel with the generation operation of the signal CR ₁ . Reference value comparing unit 112 generates a signal CR ₂ comprising the "OFF" and that the detection voltage value VD ₂ is less than the reference value V _ST, the detection voltage value VD ₂ exceeds the reference value V _ST "ON" . The signal CR ₂ generated in this way is sent to the offset determination unit 120A.

That is, the reference value comparison unit 112 compares the detection voltage values VD ₁ and VD ₂ with the reference value V _ST , thereby determining the magnitude relationship between the detection voltage values VD ₁ and VD ₂ and the reference value V _ST. Detection is performed. Then, the reference value comparison unit 112 performs ON / OFF of the signals CR ₁ and CR ₂ based on the detection result.

The above threshold value super detector 113A receives one threshold value V _TH0 specified by the offset determination unit 120A. Then, the threshold value super detector 113A performs an internal setting in which the threshold value to be referred to is the threshold value V _TH0 .

Further, the threshold value excess detection unit 113A receives the detection voltage values VD ₁ and VD ₂ sent from the voltage detection unit 111. Subsequently, the threshold ultra detector 113A compares the detected voltage value VD _1, and the threshold value V _TH0 at that time. Then, the threshold ultra detection unit 113A generates a signal OT ₁ is detected voltage value VD ₁ serving as the threshold value V _TH0 hereinafter as "OFF", and when the detected voltage value VD ₁ exceeds the threshold value V _TH0 "ON" . The signal OT ₁ generated in this way is sent to the offset determination unit 120A.

The threshold ultra detecting unit 113A, in parallel with the operation of generating signals OT _1, and compares the detected voltage value VD ₂ and the threshold V _TH0. Then, the threshold ultra detection unit 113A generates a signal OT ₂ in which the detection voltage value VD ₂ becomes "OFF" and as the threshold value V _TH0 less, when the detected voltage value VD ₂ exceeds the threshold value V _TH0 "ON" . The signal OT ₂ generated in this way is sent to the offset determination unit 120A.

<< Configuration of Offset Determination Unit 120A >>
Next, the configuration of the offset determination unit 120A described above will be described.

As shown in FIG. 3, the offset determination unit 120A includes a counting unit 121A and a determination processing unit 122A. Here, the counting unit 121A includes individual counting units (CNT) 210 ₁ and 210 ₂ .

The individual counting unit 210 ₁ receives the signals OT ₁ and CR ₁ sent from the detection unit 110A. Then, the individual counting unit 210 ₁ counts the number of times the signal OT ₁ has changed from “OFF” to “ON” during the period in which the signal CR ₁ is “ON”. Further, the individual counting unit 210 ₁ clears the count value “0” when the signal CR ₁ becomes “OFF”.

That is, the individual counting unit 210 _1, beyond the period from the detected voltage value VD ₁ exceeds the reference value V _ST to equal to or less than a reference value V _ST (detected voltage value VD ₁ is the reference value V _ST, the reference value V _The number of times that the detected voltage value VD ₁ exceeds the threshold value V _TH0 from the reference value V _ST side during the period from when the voltage value on the threshold value V _TH0 side to _ST returns to the reference value V _ST is counted. The counting result by the individual counting unit 210 ₁ is sent to the determination processing unit 122A as the count value CT ₁ .

The individual counting unit 210 ₂ receives the signals OT ₂ and CR ₂ sent from the detection unit 110A. Then, the individual counter 210 ₂ counts the number of times the signal OT ₂ has changed from “OFF” to “ON” during the period in which the signal CR ₂ is “ON”. The individual counter 210 ₂ clears the count value “0” when the signal CR ₂ becomes “OFF”.

That is, the individual counting unit 210 ₂ is greater than the period from the detection voltage value VD ₂ exceeds the reference value V _ST to equal to or less than a reference value V _ST (detected voltage value VD ₂ the reference value V _ST, the reference value V Back period until) the reference value V _ST from when the voltage value of the threshold V _TH0 side for _ST, the detection voltage value VD ₂ counts the number of times that exceeds a threshold value V _TH0 from the reference value V _ST side. The counting result obtained by the individual counting unit 210 ₂ is sent to the determination processing unit 122A as the count value CT ₂ .

The determination processing unit 122A receives the volume designation value VLS sent from the volume designation unit 400. Then, the offset determination unit 120A determines a threshold value V _TH0 corresponding to the volume designation value VLS. The threshold value V _TH0 thus determined is sent to the detection unit 110A.

The determination processing unit 122A receives the count values CT ₁ and CT ₂ sent from the counting unit 121A. Then, the determination processing unit 122A determines that the offset voltage of the output signal S ₁ is abnormal when the count value CT ₁ reaches a predetermined value N corresponding to the volume designation value VLS. Further, when the count value CT ₂ reaches the predetermined value N, the determination processing unit 122A determines that the offset voltage of the output signal S ₂ is abnormal.

If it is determined by this determination that the offset voltages of both the output signal S ₁ and the output signal S ₂ are not abnormal, it is “ON”, and the offset voltage of at least one of the output signal S ₁ and the output signal S ₂ is set. 122A, the determination processing unit 122A generates a supply control designation OSC that is “OFF”. The supply control designation OSC generated in this way is sent to the output terminal TO ₁ .

In addition, when it is determined that the offset voltages of both the output signal S ₁ and the output signal S ₂ are not abnormal, it is “OFF”, and at least one of the output signals S ₁ and S ₂ is abnormal. If it is determined, the determination processing unit 122A generates an offset abnormality instruction OAB that is “ON” in parallel with the generation operation of the supply control designation OSC. Offset abnormality indication OAB thus generated is sent to the output terminal TO _2.

FIG. 4 shows a change example in the first embodiment of the threshold value V _TH0 associated with the change in the volume designation value VLS. As shown in FIG. 4, in the first embodiment, the threshold value V _TH0 increases in a stepwise manner as the volume designation value VLS increases.

The threshold value V _TH01, V _TH02 in Figure 4, as viewed from the volume specified value VLS, and if there is no offset voltage abnormality, a voltage value that should not occur as a voltage value of the output signal S ₁ and the output signal S ₂ It is predetermined from the viewpoint. Also, the threshold _values V _TH03 , V _TH04 ,... In FIG. 4 correspond to the volume designation value VLS, and from the standpoint that the offset voltage abnormality is detected quickly and accurately and the speaker 340 is not damaged. It is determined in advance based on experiments, simulations, experiences, etc. in consideration of the specifications of 340.

When the volume designation value VLS is less than the value VLA ₂ , the predetermined value N is set to “1”. On the other hand, when the volume designation value VLS is greater than or equal to the value VLA ₂ , the predetermined value N is set to “20”, for example. The predetermined value N when the volume designated value VLS is greater than or equal to the value VLA ₂ corresponds to the volume designated value VLS, from the viewpoint of detecting the offset voltage abnormality quickly and accurately, through experiments, simulations, experiences, , Based on the specifications of the speaker 340 and the like.

<Operation>
Next, regarding the operation of the offset voltage monitoring apparatus 100A configured as described above, mainly focusing on the counting operation by the counting unit 121A of the offset determination unit 120A and the determination processing of the offset voltage abnormality by the determination processing unit 122A. explain.

Note that the volume designation unit 400 has already sent the volume designation value VLS to the offset voltage monitoring apparatus 100A. Then, the determination processing section 122A of the offset determination unit 120A determines a threshold value V _TH0, the threshold V _TH0 determined and those sent to the detection unit 110A.

Further, it is assumed that the power amplifier 320 and the detection unit 110A have already started operation, and the signals OT ₁ , OT ₂ , CR ₁ , and CR ₂ are sequentially sent to the counting unit 121A. Initially, it is assumed that the determination processing unit 122A sets the supply control designation OSC to “ON” and the offset abnormality instruction OAB to “OFF”. That is, initially, the switch elements 330 ₁ and 330 ₂ are closed, and the output signals S ₁ and S ₂ generated by the power amplifier 320 are supplied to the speaker 340.

Hereinafter, the counting operation of the individual counting unit 210 _j (j = 1, 2) of the counting unit 121A and the determination process of the offset voltage abnormality by the determination processing unit 122A based on the counting result of the individual counting unit 210 _j will be described. The counting operation of the individual counting unit 210 _j is an operation of counting the number of times the signal OT _j has changed from “OFF” to “ON” during the period in which the signal CR _j is continuously “ON”.

Note that initially, the detection voltage value VD _j is equal to or lower than the reference value V _ST , and the signal CR _j is “OFF”. As a result, it is assumed that the count value CT _j is “0”. For this reason, initially, the determination processing unit 122A determines that the offset voltage is not abnormal because the count value CT _j of the individual counting unit 210 _j does not reach the predetermined value N.

<< When the volume specification value VLS is less than the value VLA ₂ >>
First, the counting operation by the counting unit 121A and the determination processing of the offset voltage abnormality by the determination processing unit 122A when the volume designated value VLS is less than the value VLA ₂ will be described.

After the initial state described above, when the detected voltage value VD _j exceeds the reference value V _ST , the signal CR _j changes from “OFF” to “ON”. As a result, the individual counter 210 _j is ready for counting.

After the individual counter 210 _j is ready for counting in this way, when the detected voltage value VD _j changes without exceeding the threshold value V _TH0 , the count value CT _j of the individual counter 210 _j is maintained at “0”. . Thus, in the period in which the count value CT _j of the individual counting unit 210 _j is maintained at "0", the determination unit 122A, the predetermined value is the count value CT _j of the individual counting unit 210 _j N (= 1 ) Is not reached and it is determined that the offset voltage is not abnormal.

On the other hand, after the individual counting unit 210 _j becomes capable of counting, when the detected voltage value VD _j exceeds the threshold value V _TH0 , the signal OT _j changes from “OFF” to “ON”. As a result, the count value CT _j of the individual counting unit 210 _j is changed from "0" to "1".

As a result of counting by the individual counting unit 210 ₁ and the individual counting unit 210 ₂ performed in this way, at least one of the count value CT ₁ and the count value CT ₂ is a predetermined value N (= 1 when the volume designated value VLS is less than the value VLA _2. ), The determination processing unit 122A determines that an offset voltage abnormality state has occurred. Then, the determination processing unit 122A sets the supply control designation OSC to “OFF” and sets the offset abnormality instruction OAB to “ON”.

As a result, the switch elements 330 ₁ and 330 ₂ are opened, and the supply of the output signals S ₁ and S ₂ of the power amplifier 320 to the speaker 340 is stopped. Further, the information processing apparatus 500 presents an offset voltage abnormality to the user.

FIG. 5 shows an example of a timing chart of the counting operation by the individual counting unit 210 _j when the volume designated value VLS is less than the value VLA ₂ .

<< When the volume specification value VLS is greater than or equal to the value VLA ₂ >>
Next, the counting operation by the counting unit 121A and the determination processing of the offset voltage abnormality by the determination processing unit 122A when the volume designated value VLS is equal to or greater than the value VLA ₂ will be described.

After the initial state described above, when the detected voltage value VD _j exceeds the reference value V _ST , the signal CR _j changes from “OFF” to “ON”. As a result, the individual counter 210 _j is ready for counting.

After the individual counter 210 _j is ready for counting in this way, when the detected voltage value VD _j changes without exceeding the threshold value V _TH0 , the count value CT _j of the individual counter 210 _j is maintained at “0”. . On the other hand, after the individual counting unit 210 _j becomes capable of counting, when the detected voltage value VD _j exceeds the threshold value V _TH0 , the signal OT _j changes from “OFF” to “ON”. As a result, the count value CT _j of the individual counting unit 210 _j is changed from "0" to "1".

Thereafter, without becoming equal to or less than the reference value V _ST, whenever exceeding the threshold V _TH0 after the detected voltage value VD _j becomes the threshold V _TH0 less, the count value of the individual counting unit 210 _j is increased by one Go. On the other hand, when the detected voltage value VD _j becomes equal to or less than the reference value V _ST after becoming equal to or less than the threshold value V _TH0 , the count value of the individual counter 210 _j is cleared to “0”.

When at least one of the count value CT ₁ and the count value CT ₂ reaches a predetermined value N (> 1: for example, “20”) by the counting performed by the individual counting unit 210 ₁ and the individual counting unit 210 _{2 in this} way, the determination processing unit 122A determines that the offset voltage has become abnormal. Then, the determination processing unit 122A sets the supply control designation OSC to “OFF” and sets the offset abnormality instruction OAB to “ON”.

As a result, the switch elements 330 ₁ and 330 ₂ are opened, and the supply of the output signals S ₁ and S ₂ of the power amplifier 320 to the speaker 340 is stopped. Further, the information processing apparatus 500 presents an offset voltage abnormality to the user.

FIG. 6 shows an example of a timing chart of the counting operation by the individual counting unit 210 _j when the output signal S _j (j = 1, 2) of the power amplifier 320 has no offset voltage abnormality. In the example shown in FIG. 6, even if the detected voltage value VD _j of the output signal S _j exceeds the threshold value V _TH0 from the reference value V _ST side, the detection voltage value VD _j before the count value CT _j increases The count value CT _j is cleared to “0” because the reference value V _ST or less is reached. For this reason, the count value CT _j does not reach a predetermined value.

FIG. 7 shows an example of a timing chart of the counting operation by the individual counter 210 _j when the output signal S _j of the power amplifier 320 has an offset voltage abnormality. In the example shown in FIG. 7, after the detected voltage value VD _j of the output signal S _j exceeds the threshold value V _TH0 from the reference value V _ST side, the detected voltage value VD _j is without equal to or less than the reference value V _ST Then, the threshold value V _{TH0 exceeding} the reference value V _ST side is repeated. As a result, the count value CT _j increases without the count value CT _j being cleared to “0”. For this reason, the count value CT _j reaches the predetermined value N.

As described above, in the first embodiment, the detection unit 110A uses the output signals S ₁ and S ₂ of the power amplifier 320 as input signals, detects the detection voltage values VD ₁ and VD ₂ of the input signal, and detects the detection voltage value VD. ₁ , VD ₂ and the reference value V _ST are detected, and the detection voltage values VD ₁ and VD ₂ are exceeded for one threshold value V _TH0 . Here, the threshold value V _TH0 is determined by the offset determination unit 120A based on the volume designation value VLS sent from the volume designation unit 400.

Subsequently, for each of the detected voltage value VD _1, VD _2, the counting unit 121A of the offset determination unit 120A is the period from exceeding the reference value V _ST until below the reference value V _ST, the detection voltage value VD ₁ The number of times that the threshold value V _TH0 has been exceeded from the reference value V _ST side and the number of times that the detection voltage value VD ₂ has exceeded the threshold value V _TH from the reference value V _ST side are counted. Then, the determination processing unit 122A in the offset determination unit 120A determines that there is an offset voltage abnormality when one of the two counting results by the counting unit 121A reaches a predetermined value.

  Therefore, according to the first embodiment, it is possible to always monitor an appropriate offset voltage corresponding to the volume designated value with a simple configuration in which the timer function is not implemented.

In the first embodiment, the offset determination unit 120A determines that the voltage values VD ₁ and VD ₂ of the input signals S ₁ and S ₂ are the volume designation when the volume designation value VLS is less than the predetermined value VLA _2. If the threshold value V _TH0 determined based on the value VLS is exceeded even once, it is determined that the offset voltages of the input signals S ₁ and S ₂ are abnormal. When the volume designated value VLS is equal to or greater than a predetermined value VLA ₂ , the voltage values VD ₁ and VD ₂ of the input signals S ₁ and S ₂ change beyond the reference value V _ST toward the threshold value V _TH0 . from to, until the voltage value VD _1, VD ₂ of the input signal S _1, S ₂ is returned to the reference value V _ST, the voltage value VD _1, VD ₂ input signals S _1, S _2, reference value V _ST Whether the offset voltages of the input signals S ₁ and S ₂ are abnormal is determined based on the number of changes from the side that exceed the threshold value V _TH0 . For this reason, it is possible to monitor a reasonable offset voltage corresponding to the volume designated value VLS.

In the first embodiment, an output terminal TO ₂ for outputting the determination result by the offset determination unit 120A to the outside is provided. For this reason, the occurrence of the offset voltage abnormality can be notified to the outside.

In the first embodiment, when the offset determination unit 120A determines that the offset voltage is abnormal, control is performed to stop the supply of the output signals S ₁ and S ₂ from the power amplifier 320 to the speaker 340. . For this reason, when the offset voltage is abnormal, the supply of the output signals S ₁ and S ₂ from the power amplifier 320 to the speaker 340 can be quickly stopped.

[Second Embodiment]
Next, a second embodiment of the present invention will be described mainly with reference to FIGS.

<Configuration>
FIG. 8 is a block diagram showing a schematic configuration of the offset voltage monitoring apparatus 100B according to the second embodiment. As shown in FIG. 8, the offset voltage monitoring device 100B includes a detection unit 110B instead of the detection unit 110A, compared to the offset voltage monitoring device 100A (see FIG. 1) of the first embodiment described above. And the point provided with the offset determination part 120B instead of the offset determination part 120A is different. Hereinafter, description will be made mainly focusing on these differences.

<< Configuration of Detection Unit 110B >>
As shown in FIG. 9, the detection unit 110B is different from the detection unit 110A (see FIG. 2) described above in that a threshold value super detection unit 113B is provided instead of the threshold value super detection unit 113A. Yes.

The threshold value excess detection unit 113B receives the first threshold value V _TH1 (> 0) and the second threshold value V _TH2 (> V _TH1 ) sent from the offset determination unit 120B. Then, the threshold value excess detection unit 113B performs an internal setting in which the threshold value to be referred to is the first threshold value V _TH1 and the second threshold value V _TH2 .

Further, the threshold value excess detection unit 113B receives the detection voltage values VD ₁ and VD ₂ sent from the voltage detection unit 111. Subsequently, the threshold ultra detector 113B compares the detected voltage value VD ₁ and the first threshold value V _TH1. Then, the threshold ultra detector 113B is "OFF" and that the detection voltage value VD ₁ is equal to or smaller than the first threshold value V _TH1, the signal OT of the detection voltage value VD ₁ comprising exceeds the first threshold value V _TH1 "ON" ₁₁ is generated. The signal OT ₁₁ generated in this way is sent to the offset determination unit 120B.

The threshold ultra detector 113B, in parallel with the generation operation of the signal OT _11, compares the detection voltage VD ₁ and the second threshold value V _TH2. Then, the threshold ultra detector 113B, the detected voltage value "OFF" and the VD ₁ is equal to or less than the second threshold value V _TH2, the signal is detected voltage value VD ₁ comprising exceeds the second threshold value V _TH2 "ON" OT Generates ₁₂ . Signal OT ₁₂ thus generated is sent to the offset determination unit 120B.

Furthermore, the threshold ultra detector 113B, in parallel with the generation operation of the signal OT _11, OT _12, compares the detection voltage VD ₂ and the first threshold value V _TH1. Then, the threshold ultra detector 113B includes a detection voltage VD ₂ is equal to or smaller than the first threshold value V _TH1 "OFF" and if the detected voltage value VD ₂ exceeds the first threshold value V _TH1 is "ON" signal OT Generate ₂₁ . Signal OT ₂₁ thus generated is sent to the offset determination unit 120B.

The threshold ultra detector 113B, in parallel with the generation operation of the signal _{OT 11, OT 12, OT 21} , compares the detection voltage VD ₂ and the second threshold value V _TH2. Then, the threshold ultra detector 113B is "OFF" and that the detection voltage value VD ₂ is equal to or less than the second threshold value V _TH2, the signal is detected voltage value VD ₂ consists exceeds the second threshold value V _TH2 "ON" OT Generates ₂₂ . The signal OT ₂₂ generated in this way is sent to the offset determination unit 120B.

<< Configuration of Offset Determination Unit 120B >>
Next, the configuration of the offset determination unit 120B will be described.

  As shown in FIG. 10, the offset determination unit 120B is different from the offset determination unit 120A described above in that it includes a counting unit 121B instead of the counting unit 121A. Further, the offset determination unit 120B is different from the offset determination unit 120A in that a determination processing unit 122B is provided instead of the determination processing unit 122A.

The counting unit 121B receives the signals CR ₁ , OT ₁₁ , OT ₁₂ and the signals CR ₂ , OT ₂₁ , OT ₂₂ sent from the detection unit 110B. Then, the counting unit 121B generates the sum count value ACT ₁ and the difference count value SCT ₁ based on the signals CR ₁ , OT ₁₁ , OT ₁₂ as described later. The counting unit 121B generates the sum count value ACT ₂ and the difference count value SCT ₂ as described later based on the signals CR ₂ , OT ₂₁ , and OT ₂₂ . The sum count values ACT ₁ and ACT ₂ and the difference count values SCT ₁ and SCT ₂ generated in this way are sent to the determination processing unit 122B.

  Details of the configuration of the counting unit 121B will be described later.

The determination processing unit 122B receives the volume designation value VLS sent from the volume designation unit 400. Then, the offset determination unit 120B determines the first threshold value V _TH1 and the second threshold value V _TH2 corresponding to the volume designation value VLS. The first threshold value V _TH1 and the second threshold value V _TH2 determined in this way are sent to the detection unit 110B.

The determination processing unit 122B receives the sum count values ACT ₁ and ACT ₂ and the difference count values SCT ₁ and SCT ₂ sent from the counting unit 121B. Then, the determination processing unit 122B determines that the offset voltage of the output signal S ₁ is abnormal when the sum count value ACT ₁ reaches the first predetermined value N ₁ (for example, “20”). In addition, the determination processing unit 122B also determines that the offset voltage of the output signal S ₁ is different even when the difference count value SCT ₁ reaches the second predetermined value N ₂ (<(N ₁ -2): “5”, for example). Judged to be abnormal.

Further, the determination processing unit 122B determines that if the sum count value ACT ₂ reaches a first predetermined value N _1, the offset voltage of the output signal S ₂ is abnormal. Further, the determination processing unit 122B determines that the difference count SCT ₂ even when it reaches the second predetermined value N _2, the offset voltage of the output signal S ₂ is abnormal.

The first predetermined value N ₁ and the second predetermined value N ₂ are preliminarily determined based on experiments, simulations, experiences, the specifications of the speaker 340, etc. from the viewpoint of detecting the offset voltage abnormality quickly and appropriately. Determined.

If it is determined by this determination that the offset voltages of both the output signal S ₁ and the output signal S ₂ are not abnormal, it is “ON”, and the offset voltage of at least one of the output signal S ₁ and the output signal S ₂ is set. If it is determined that the operation is abnormal, the determination processing unit 122B generates a supply control designation OSC that is “OFF”. The supply control designation OSC generated in this way is sent to the output terminal TO ₁ .

In addition, when it is determined that the offset voltages of both the output signal S ₁ and the output signal S ₂ are not abnormal, it is “OFF”, and at least one of the output signals S ₁ and S ₂ is abnormal. If it is determined, the determination processing unit 122B generates an offset abnormality instruction OAB that is “ON” in parallel with the generation operation of the supply control designation OSC. Offset abnormality indication OAB thus generated is sent to the output terminal TO _2.

(Configuration of counting unit 121B)
Next, the configuration of the counting unit 121B will be described.

As shown in FIG. 11, the counting unit 121B includes individual counting units 210 ₁₁ , 210 ₁₂ , 210 ₂₁ , and 210 ₂₂ . The counting unit 121B includes addition units 221 ₁ and 221 ₂ and subtraction units 222 ₁ and 222 ₂ .

The individual counting unit 210 ₁₁ receives the signals OT ₁₁ and CR ₁ sent from the detection unit 110B. Then, the individual counting unit 210 ₁₁ counts the number of times that the signal OT ₁₁ has changed from “OFF” to “ON” during the period in which the signal CR ₁ is “ON”. Furthermore, the individual counting unit 210 _11, when the signal CR ₁ is "OFF", to "0" clears the count value.

That is, the individual counting unit 210 _11, a period from the detection voltage VD ₁ exceeds the reference value V _ST until below the reference value V _ST, first threshold detection voltage VD ₁ from the reference value V _ST side Count the number of times V _TH1 was exceeded. The counting result obtained by the individual counting unit 210 ₁₁ is sent to the adding unit 221 ₁ and the subtracting unit 222 ₁ as the count value CT ₁₁ .

The individual counting unit 210 ₁₂ receives the signals OT ₁₂ and CR ₁ sent from the detection unit 110B. Then, the individual counter 210 ₁₂ counts the number of times that the signal OT ₁₂ has changed from “OFF” to “ON” during the period in which the signal CR ₁ is “ON”. Furthermore, the individual counting unit 210 _12, when the signal CR ₁ is "OFF", to "0" clears the count value.

That is, the individual counting unit 210 _12, a period from the detection voltage VD ₁ exceeds the reference value V _ST until below the reference value V _ST, second threshold detection voltage VD ₁ from the reference value V _ST side Count the number of times that V _TH2 was exceeded. The counting result of the individual counting unit 210 ₁₂ is sent to the adding unit 221 ₁ and the subtracting unit 222 ₁ as the count value CT ₁₂ .

The individual counting unit 210 ₂₁ receives the signals OT ₂₁ and CR ₂ sent from the detection unit 110B. Then, the individual counting unit 210 ₂₁ counts the number of times that the signal OT ₂₁ has changed from “OFF” to “ON” during the period in which the signal CR ₂ is “ON”. Further, the individual counting unit 210 ₂₁ clears the count value by “0” when the signal CR ₂ becomes “OFF”.

That is, the individual counting unit 210 _21, a period from the detection voltage value VD ₂ exceeds the reference value V _ST until below the reference value V _ST, first threshold is detected voltage value VD ₂ from the reference value V _ST side Count the number of times V _TH1 was exceeded. The counting result by the individual counting unit 210 ₂₁ is sent to the adding unit 221 ₂ and the subtracting unit 222 ₂ as the count value CT ₂₁ .

The individual counting unit 210 ₂₂ receives the signals OT ₂₂ and CR ₂ sent from the detection unit 110B. The individual counter 210 ₂₂ counts the number of times the signal OT ₂₂ has changed from “OFF” to “ON” during the period in which the signal CR ₂ is “ON”. Furthermore, the individual counting unit 210 _22, when the signal CR ₂ is "OFF", to "0" clears the count value.

That is, the individual counting unit 210 _22, a period from the detection voltage value VD ₂ exceeds the reference value V _ST until below the reference value V _ST, the second threshold is detected voltage value VD ₂ from the reference value V _ST side Count the number of times that V _TH2 was exceeded. The counting result by the individual counting unit 210 ₂₂ is sent to the adding unit 221 ₂ and the subtracting unit 222 ₂ as the count value CT ₂₂ .

The adder 221 ₁ receives the count value CT ₁₁ sent from the individual count unit 210 ₁₁ and the count value CT ₁₂ sent from the individual count unit 210 ₁₂ . Then, the adding unit 221 ₁ adds the count value CT ₁₁ and the count value CT ₁₂ . Result of such addition is as a sum count ACT _1, is sent to the determination processing unit 122B.

The adder 221 ₂ receives the count value CT ₂₁ sent from the individual count unit 210 ₂₁ and the count value CT ₂₂ sent from the individual count unit 210 ₂₂ . Then, the adder 221 ₂ adds the count value CT ₂₁ and the count value CT ₂₂ . Result of such addition is as a sum count ACT _2, is sent to the determination processing unit 122B.

The subtracting unit 222 ₁ receives the count value CT ₁₁ sent from the individual counting unit 210 ₁₁ and the count value CT ₁₂ sent from the individual counting unit 210 ₁₂ . Then, the subtracting unit 222 ₁ subtracts the count value CT ₁₁ from the count value CT ₁₂ . Result of such subtraction as the difference count SCT _1, is sent to the determination processing unit 122B.

The subtractor 222 ₂ receives the count value CT ₂₁ sent from the individual counter 210 ₂₁ and the count value CT ₂₂ sent from the individual counter 210 ₂₂ . The subtraction unit 222 ₂ subtracts from the count value CT ₂₂ counts CT _21. Result of such subtraction as the difference count SCT _2, is sent to the determination processing unit 122B.

FIG. 12 shows a change example in the second embodiment of the first threshold value V _TH1 and the second threshold value V _TH2 in accordance with the change in the volume designation value VLS. In FIG. 12, the change in the first threshold value V _TH1 is indicated by a one-dot chain line, and the change in the second threshold value V _TH2 is indicated by a two-dot chain line.

As shown in FIG. 12, in the second embodiment, the first threshold value V _TH1 and the second threshold value V _TH2 increase stepwise as the volume designation value VLS increases. The difference between the first threshold value V _TH1 and the second threshold value V _TH2 corresponding to the same volume designated value VLS is also increased stepwise as the volume designated value VLS increases.

The values V _TH11 ,... And the values V _TH21 ,... In FIG. 12 correspond to the volume designation value VLS, from the viewpoint of detecting the offset voltage abnormality quickly and accurately, and the specifications of the speaker 340. Is determined in advance based on experiments, simulations, experiences, or the like.

<Operation>
Next, the operation of the offset voltage monitoring apparatus 100B configured as described above will be described mainly focusing on the counting operation performed by the counting unit 121B and the offset voltage abnormality determination processing performed by the determination processing unit 122B.

Note that the volume designation unit 400 has already sent the volume designation value VLS to the offset voltage monitoring apparatus 100B. Then, the determination processing unit 122B of the offset determination unit 120B has sent the first threshold value V _TH1 and second threshold value V _TH2 for determining the first threshold value V _TH1 and second threshold value V _TH2, was determined to detector 110B Shall.

The power amplifier 320 and the detection unit 110B have already started operation, and the signals OT ₁₁ , OT ₁₂ , OT ₂₁ , OT ₂₂ , CR ₁ , CR ₂ are sequentially sent to the counting unit 121B. To do. Initially, it is assumed that the determination processing unit 122B sets the supply control designation OSC to “ON” and the offset abnormality instruction OAB to “OFF”. That is, initially, the switch elements 330 ₁ and 330 ₂ are closed, and the output signals S ₁ and S ₂ generated by the power amplifier 320 are supplied to the speaker 340.

Note that initially, the detection voltage value VD _j is equal to or lower than the reference value V _ST , and the signal CR _j is “OFF”. As a result, it is assumed that the count value CT _j is “0”. Therefore, initially, neither the sum count values ACT ₁ and ACT ₂ reach the first predetermined value N ₁ , and both the difference count values SCT ₁ and SCT ₂ reach the second predetermined value N ₂ . Since it has not reached, the determination processing unit 122B determines that the offset voltage is not abnormal.

After such an initial state, when the detected voltage value VD _j exceeds the reference value V _ST , the signal CR _j changes from “OFF” to “ON”. As a result, the individual counters 210 _j1 and 210 _j2 are in a countable state. After the individual counters 210 _j1 and 210 _j2 become _countable , if the detected voltage value VD _j changes without exceeding the first threshold value V _TH1 , the count values CT _j1 and 210 _j2 of the individual counters 210 _j1 and 210 _j2 CT _j2 is maintained at “0”. As a result, the sum count values ACT ₁ and ACT ₂ and the difference count values SCT ₁ and SCT ₂ are maintained at “0”.

On the other hand, after the individual counters 210 _j1 and 210 _j2 are ready for counting, when the detection voltage value VD _j exceeds the first threshold value V _TH1 and the signal OT _j1 changes from “OFF” to “ON”, the count value CT _j1 of the counting unit 210 _j1 is changed from "0" to "1". As a result, the sum count value ACT _j changes from “0” to “1”. Further, the difference count value SCT _j changes from “0” to “−1”.

Thereafter, when the detection voltage value VD _j exceeds the second threshold value V _TH2 and the signal OT _j2 changes from “OFF” to “ON” without the detection voltage value VD _j becoming equal to or lower than the first threshold value V _TH1 , individual the count value CT _j2 of the counting unit 210 _j2 is changed from "0" to "1". As a result, the sum count value ACT _j changes from “1” to “2”. Further, the difference count value SCT _j changes from “−1” to “0”.

Further, after as described above count value CT _j1 of the individual counting unit 210 _j1 changes from "0" to "1", the detected voltage value VD _j without exceeding the second threshold value V _TH2 first threshold value V _TH1 The _count value CT _j1 changes from “1” to “2” when the first threshold value V _TH1 is exceeded again without going below the reference value V _ST . As a result, the sum count value ACT _j changes from “1” to “2”. Further, the difference count value SCT _j changes from “−1” to “−2”.

As described above, the _count value CT _j1 increases by 1 each time the first threshold value V _TH1 is exceeded while the detection voltage value VD _j is not lower than the reference value V _ST . As a result, the sum count value ACT _j increases by “1”, and the difference count value SCT _j decreases by “1”.

The _count value CT _j2 increases by 1 each time the second threshold value V _TH2 is _exceeded while the detection voltage value VD _j is not equal to or lower than the reference value V _ST . As a result, the sum count value ACT _j increases by “1”, and the difference count value SCT _j increases by “1”.

On the other hand, when the detection voltage value VD ₁ is equal to or lower than the reference value V _ST , the count values CT ₁₁ and CT ₁₂ are both “0”. As a result, the sum count values ACT ₁ and ACT ₂ and the difference count values SCT ₁ and SCT ₂ become “0”.

When _one of the sum count values ACT ₁ and ACT ₂ reaches the first predetermined value N ₁ by the counting operation in the counting unit 121B performed in this way, the determination processing unit 122B determines that the offset voltage has become abnormal. . Further, also when any _{one of} the difference count values SCT ₁ and SCT ₂ reaches the second predetermined value N ₂ , the determination processing unit 122B determines that the offset voltage is abnormal. Then, the determination processing unit 122B sets the supply control designation OSC to “OFF” and sets the offset abnormality instruction OAB to “ON”.

As a result, the switch elements 330 ₁ and 330 ₂ are opened, and the supply of the output signals S ₁ and S ₂ of the power amplifier 320 to the speaker 340 is stopped. Further, the information processing apparatus 500 presents an offset voltage abnormality to the user.

FIG. 13 shows an example of a timing chart of the counting operation in the counting unit 121B when there is no offset voltage abnormality in the output signal S _j (j = 1, 2) of the power amplifier 320. In the example shown in FIG. 13, even if the detected voltage value VD _j of the output signal S _j has exceeded the first threshold value V _TH1 or the second threshold value V _TH2 from the reference value V _ST side, the sum count ACT _1, ACT ₂ or before the difference count values SCT ₁ and SCT ₂ increase, the detection voltage value VD _j becomes equal to or less than the reference value V _ST and the count value CT _j is cleared to “0”. Therefore, neither the sum count value ACT ₁ or ACT ₂ reaches the first predetermined value N _1, and neither the difference count value SCT ₁ or SCT ₂ reaches the second predetermined value N _2.

FIG. 14 shows a first example of a timing chart of the counting operation in the counting unit 121B when the output signal S _j of the power amplifier 320 has an offset voltage abnormality. In the first example, after the detected voltage value VD _j of the output signal S _j has exceeded the first threshold value V _TH1 from the reference value V _ST side, the detected voltage value VD _j is the reference value V _ST follows without being, repeating the second threshold value V _TH2 greater than the reference value V _ST side and a first threshold value V _TH1 greater than the reference value V _ST side. As a result, in the first example, the difference count value SCT _j does not reach the second predetermined value N ₂ , but the sum count value ACT _j increases and reaches the first predetermined value N ₁ .

FIG. 15 shows a second example of a timing chart of the counting operation in the counting unit 121B when the output signal S _j of the power amplifier 320 has an offset voltage abnormality. The second example is an example in which the offset voltage abnormality is higher than in the first example described above.

In the second example, after the detected voltage value VD _j of the output signal S _j is the first threshold value V _TH1 exceeds a reference value V _ST side, exceeds the second threshold value V _TH2 from further reference value V _ST side, the detected voltage value The second threshold value V _TH2 from the reference value V _ST side is repeated without VD _j becoming equal to or less than the first threshold value V _TH1 . As a result, both the sum count value ACT _j and the difference count value SCT _j increase. Then, before the sum count value ACT _j reaches the first predetermined value N ₁ , the difference count value SCT _j reaches the second predetermined value N ₂ . For this reason, when the offset voltage abnormality is higher than when only the sum count value ACT _j is monitored to reach the first predetermined value N ₁ , the state of the offset voltage abnormality can be detected quickly.

As described above, in the second embodiment, the detection unit 110B uses the output signals S ₁ and S ₂ of the power amplifier 320 as input signals, detects the detection voltage values VD ₁ and VD ₂ of the input signal, and detects the detection voltage value VD. ₁ , detection of magnitude relationship between VD ₂ and reference value V _ST , and detection voltage values VD ₁ , VD ₂ exceed reference value V _ST for each of two threshold values V _TH1 , V _TH2 (> V _TH1 ) Detect that. Here, the threshold values V _TH1 and V _TH2 are determined by the offset determination unit 120B based on the volume designation value VLS sent from the volume designation unit 400.

Subsequently, the counting unit 121B in the offset determination unit 120B is, the period from exceeding the reference value V _ST until below the reference value V _ST, threshold greater than the reference value V _ST for every two thresholds V _TH1, V _TH2 The sum count value and the difference count value are obtained for each of the detection voltage values VD ₁ and VD ₂ . Then, the determination processing unit 122B in the offset determination unit 120B determines whether there is an offset voltage abnormality based on the counting result by the counting unit 121B.

Therefore, according to the second embodiment, as in the case of the first embodiment described above, it is possible to always monitor an appropriate offset voltage corresponding to the volume specified value with a simple configuration in which the timer function is not implemented. it can. Furthermore, according to the second embodiment, since it is determined whether or not there is an offset voltage abnormality based on the sum count value and the difference count value of the number of times exceeding the threshold for each of the two threshold values V _TH1 and V _TH2 , the first The offset voltage can be constantly monitored in such a manner that the offset voltage abnormality can be detected more rapidly as the probability of occurrence of the offset voltage abnormality is higher than in the case of the embodiment.

The second embodiment further includes an output terminal TO ₂ for outputting the determination result by the offset determination unit 120B to the outside, as in the case of the first embodiment. For this reason, the occurrence of the offset voltage abnormality can be notified to the outside.

Further, in the second embodiment, as in the case of the first embodiment, when the offset determination unit 120B determines that the offset voltage is abnormal, the output signal S ₁ from the power amplifier 320 to the speaker 340, Control to stop the supply of S ₂ is performed. For this reason, when the offset voltage is abnormal, the supply of the output signals S ₁ and S ₂ from the power amplifier 320 to the speaker 340 can be quickly stopped.

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

  For example, in the first and second embodiments, the offset voltage is monitored for each of the two output signals of the power amplifier. On the other hand, when one signal in the two output signals of the power amplifier is generated based on the other signal, the offset voltage may be monitored only for the one signal. .

  Further, when the output signal is a single signal as in a home acoustic device, the offset voltage may be monitored for the single signal.

  The offset voltage may be monitored based on the voltage difference between the two output signals of the power amplifier. In this case, the reference value is “0” V. Then, for example, the number of times that the absolute value of the voltage difference exceeds the absolute value of the threshold may be counted.

In the first embodiment, the threshold value V _TH0 is changed according to the change of the volume specification value even in the range of the volume specification value where the predetermined value N is “1”. On the other hand, the threshold value V _TH0 may not be changed in the volume specification value range in which the predetermined value N is “1”.

In the first embodiment, the threshold value V _TH0 is changed discretely (stepwise) according to the change of the volume designation value. On the other hand, the threshold value V _TH0 may be continuously changed according to the change of the volume designation value.

In the second embodiment, the difference between the first threshold value V _TH1 and the second threshold value V _TH2 is increased when the volume specification value VLS is increased. On the other hand, even if the volume designation value VLS changes, the difference between the first threshold value V _TH1 and the second threshold value V _TH2 may be made constant.

In the second embodiment, both the first threshold value V _TH1 and the second threshold value V _TH2 are changed according to the change in the volume designation value VLS. On the other hand, only the second threshold value V _TH2 is changed according to the change of the volume designation value VLS.

In the second embodiment, the first threshold value V _TH1 and the second threshold value V _TH2 are changed discretely (stepwise) according to the change in the volume designated value. On the other hand, at least one of the first threshold value V _TH1 and the second threshold value V _TH2 may be continuously changed according to the change of the volume designation value.

In the second embodiment, when calculating the sum _count value, the simple sum of the _count value _exceeding the first threshold value V _TH1 and the _count value _exceeding the second threshold value V _TH2 is calculated. On the other hand, the sum count value may be calculated by performing weighted addition in which the weight of the count value _exceeding the second threshold V _TH2 is made larger than the weight for the count value _exceeding the first threshold V _TH1 .

  In the second embodiment, two threshold types are used, but three or more threshold values may be adopted.

  In the first and second embodiments described above, the individual counting unit determines that the threshold is exceeded when the counting target signal is changed from “OFF” to “ON”, and the counting target signal is changed from “OFF”. By counting the number of changes to “ON”, the threshold value was exceeded. On the other hand, the individual counting unit determines that the threshold is exceeded when the counting target signal has changed from “ON” to “OFF”, and determines the number of times the counting target signal has changed from “ON” to “OFF”. You may make it count over a threshold value by counting.

  In the first and second embodiments, the offset voltages of the two output signals of the power amplifier are monitored. However, the present invention can be applied to monitoring the offset voltages of other types of signals. Good.

  In the first and second embodiments, the reference value and the threshold value are positive values. However, the present invention may be applied to a case where at least one of the reference value and the threshold value is a negative value.

  In the first and second embodiments, it is assumed that the volume specifying unit 400 and the information processing apparatus 500 are different apparatuses. On the other hand, the function of the volume specifying unit 400 and the function performed by the information processing apparatus 500 may be performed by the same apparatus.

  In addition, the offset determination part in said 1st or 2nd embodiment is comprised as a computer as a calculating means provided with the central processing unit (CPU: Central Processing Unit) etc., and the program prepared beforehand is run with the said computer As a result, part or all of the processing in the offset determination unit may be executed. This program is recorded on a computer-readable recording medium such as a hard disk, CD-ROM, or DVD, and is loaded from the recording medium and executed by the computer. The program may be acquired in a form recorded on a portable recording medium such as a CD-ROM or DVD, or may be acquired in a form distributed via a network such as the Internet. Also good.

100A, 100B ... Offset voltage monitoring device 110A, 110B ... Detection unit 120A, 120B ... Offset determination unit

Claims (10)

Detection of the voltage value of the input signal, detection of the magnitude relationship between the voltage value of the input signal and a reference value, and the voltage value of the input signal exceeded at least one threshold set on one side with respect to the reference value A detection unit for detecting that;
An acquisition unit for acquiring a specified value;
An offset determination unit that determines whether an offset voltage of the input signal is abnormal based on a detection result by the detection unit, the acquired designated value, and the at least one threshold;
An offset voltage monitoring device comprising:   The offset voltage monitoring apparatus according to claim 1, wherein the specified value is a value that specifies a difference between a maximum value and a minimum value of a voltage value of the input signal. The at least one threshold includes one threshold,
The offset determination unit
When the specified value is less than a predetermined value, when the voltage value of the input signal exceeds the one threshold, it is determined that the offset voltage of the input signal is abnormal,
When the specified value is greater than or equal to the predetermined value, the voltage value of the input signal changes from the one side after the voltage value of the input signal exceeds the reference value and changes to the one side. Determining whether the offset voltage of the input signal is abnormal based on the number of changes in the voltage value of the input signal exceeding the at least one threshold before returning to the reference value;
The offset voltage monitoring apparatus according to claim 1 or 2, wherein   The offset determination unit, when the specified value is greater than or equal to the predetermined value, changes one or more of the at least one threshold according to the specified value, The offset voltage monitoring device according to claim 3. The offset determination unit
Changing one or more thresholds of the at least one threshold according to the specified value;
After the voltage value of the input signal changes to the one side exceeding the reference value, the voltage value of the input signal is at least the time from when the voltage value of the input signal returns to the reference value from the one side. Determining whether the offset voltage of the input signal is abnormal based on the number of changes exceeding one threshold;
The offset voltage monitoring apparatus according to claim 1 or 2, wherein The at least one threshold includes a plurality of thresholds;
The offset voltage monitoring apparatus according to claim 4, wherein the offset determination unit changes the one or more threshold values in any of the following aspects (a) to (c):
(A) According to the specified value, among the plurality of threshold values, a threshold value having a maximum difference from the reference value is changed.
(B) changing the plurality of thresholds according to the designated value so that a difference between the plurality of thresholds is maintained; and
(C) In accordance with the specified value, as the specified value increases, the amount of change is increased as the threshold value is larger than the reference value. The at least one threshold includes a plurality of thresholds;
The offset determination unit
Performing a first count that counts the number of times that the voltage value of the input signal has changed such that the difference between the two adjacent threshold values and the reference value exceeds a larger threshold value;
In parallel with the first count, a second count for counting the number of times that the voltage value of the input signal has changed a difference between the threshold value of the two adjacent threshold values exceeding a smaller threshold value is performed. ,
Determining whether the offset voltage of the input signal is abnormal when the number of differences obtained by subtracting the result of the second count from the result of the first count is a predetermined number of times;
The offset voltage monitoring apparatus according to any one of claims 4 to 6, wherein Detection of the voltage value of the input signal, detection of the magnitude relationship between the voltage value of the input signal and the reference value, and the voltage value of the input signal exceeded at least one threshold set on one side with respect to the reference value An offset voltage monitoring method used in an offset voltage monitoring device that includes a detection unit that detects the above, and monitors an offset voltage in the input signal,
A first acquisition step of acquiring a specified value;
A second acquisition step of acquiring a detection result by the detection unit;
An offset determination step of determining whether the offset voltage of the input signal is abnormal based on the acquisition result in the first acquisition step, the acquisition result in the second acquisition step, and the at least one threshold;
An offset voltage monitoring method comprising:   9. An offset voltage monitoring program that causes a computer included in an offset voltage monitoring apparatus that monitors an offset voltage in an input signal to be executed to execute the offset voltage monitoring method according to claim 8.   10. A recording medium, wherein the offset voltage monitoring program according to claim 9 is recorded so as to be readable by a computer included in an offset voltage monitoring device that monitors an offset voltage in an input signal that has been input.

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