JP7265134B2 - Measuring device, measuring system and measuring method - Google Patents

Description

The present invention relates to a measuring device, a measuring system, and a measuring method.

The fatigue level measuring device described in Patent Document 1 includes an environmental change determination unit that determines an environmental change of a traveling vehicle, and an operation determination unit that determines whether operation of on-vehicle equipment is necessary depending on the determined environmental change. , a voice output unit for presenting an inquiry to the occupant as to whether or not to operate the in-vehicle device determined to be necessary, a voice input unit for inputting an instruction to operate the in-vehicle device by voice, and a voice input by the occupant It consists of an in-vehicle equipment control unit that controls the operation of the in-vehicle equipment based on the operation instructions input to the unit, and a fatigue level measurement unit that measures the fatigue level from the voice uttered by the passenger in response to an inquiry by at least the voice output unit. be.

JP-A-2003-310583

However, the fatigue level measuring device described in Patent Document 1 is not carried by a passenger, but is mounted on a vehicle, so there is no concern about power consumption.

The present invention has been made in view of the above problems, and suppresses the amount of power supplied by the power supply by changing the amount of power supplied by the power supply according to the timing of the speaker's speech and the volume of the speech. An object of the present invention is to provide a measuring device, a measuring system, and a measuring method that can

According to one aspect of the present invention, a measurement device includes a generator, a first frequency controller, a power supply, and a power controller. The generator generates speech information from the speaker's speech at a sampling frequency. The first frequency control section controls the sampling frequency. The power supply supplies power to the generator. The power control unit controls the power supply amount based on the sampling frequency.

According to the present invention, by changing the amount of power supplied by the power supply according to the timing when the speaker speaks and the volume of the utterance, the amount of power supplied by the power supply can be suppressed.

1 is a diagram showing a typical example of a measurement system and measurement device according to this embodiment of the present invention; FIG. 4 is a flow chart showing an example of the operation of a typical example of the measurement system and measurement device according to the present embodiment. It is a figure which shows the specific example of the measuring system and measuring device which concern on this embodiment. 5 is a flow chart showing an example of the operation of a specific example of the measurement system and measurement device according to the present embodiment. 5 is a flow chart showing an example of the operation of a specific example of the measurement system and measurement device according to the present embodiment. 5 is a flow chart showing an example of the operation of a specific example of the measurement system and measurement device according to the present embodiment. 5 is a flow chart showing an example of the operation of a specific example of the measurement system and measurement device according to the present embodiment. It is a figure which shows the modification of the measurement system which concerns on this embodiment, and a measurement apparatus. It is a figure which shows the modification of the measurement system which concerns on this embodiment, and a measurement apparatus. It is a figure which shows the modification of the measurement system which concerns on this embodiment, and a measurement apparatus. It is a figure which shows the modification of the measurement system which concerns on this embodiment, and a measurement apparatus.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals, and description thereof will not be repeated.

(Typical example)
A typical example of a measurement system 2 and a measurement device 6 according to this embodiment will be described with reference to FIG. FIG. 1 is a diagram showing a typical example of a measurement system 2 and a measurement device 6. As shown in FIG.

As shown in FIG. 1, the measurement system 2 comprises a measurement device 6 and an integrator 24 .

Measuring device 6 is typically carried by speaker 4 . The integration device 24 is connected to the measurement device 6 via the communication line 22 . The communication line 22 may be a wired communication line or a wireless communication line.

Examples of wired communication lines include telephone lines, ISDN (Integrated Services Digital Network) lines, ADSL (Asymmetric Digital Subscriber Line) lines, wired LAN (Local Area Network) lines, wired WAN (Wide Area Network) lines, optical fiber lines, and cables. TV line or internet line.

Examples of wireless communication lines are LTE (Long Term Evolution) lines, wi-fi (Wireless Fidelity) lines, wireless LAN lines, wireless WAN lines, or satellite communication lines.

The measurement device 6 includes a sound collector 8 , a generator 10 , a first frequency controller 12 , a power supply 14 , a power controller 16 , a first communication unit 18 and a first measurement unit 20 . The measuring device 6 includes a CPU (Central Processing Unit) (not shown) and a storage device such as a RAM (Random Access Memory). Each function of the measurement unit 20 is realized.

The sound collector 8 collects the voice of the speaker 4 . An example of the sound collector 8 is a small microphone. The generator 10 generates speech information from the speech of the speaker 4 at the sampling frequency f. The first frequency control section 12 controls the sampling frequency f. The power supply 14 supplies power to the generator 10 . The power control unit 16 controls the amount of power supply based on the sampling frequency f. The first communication unit 18 communicates with the integrated device 24 via the communication line 22 . The first measuring unit 20 estimates the amount of change in volume Vo included in the audio information.

Aggregation device 24 may be hub device 34 or server device 36 . The integrated device 24 may be a hub device 34 or a server device 36 . Alternatively, the integrated device 24 may be a combination of a hub device 34 and a server device 36 .

The integrated device 24 includes a second communication section 26 , a second frequency control section 28 , a second measurement section 30 and an analysis section 32 . If the integrated device 24 is a combination of the hub device 34 and the server device 36, the second communication section 26 to analysis section 32 may be arranged anywhere.

The second communication section 26 communicates with the first communication section 18 of the measuring device 6 via the communication line 22 .

The second frequency control section 28 has the same function as the first frequency control section 12, and functions as either the first frequency control section 12 or the second frequency control section 28 as the frequency control section. Therefore, at least one of the first frequency control section 12 and the second frequency control section 28 should be included in the measuring device 6 or the integrating device 24 . That is, if the measuring device 6 has the first frequency control section 12 , the integrated device 24 need not have the second frequency control section 28 . If the integrated device 24 has the second frequency control section 28 , the measuring device 6 need not have the first frequency control section 12 .

The second measurement unit 30 estimates the amount of change in volume Vo included in the audio information. The first measurement section 20 and the second measurement section 30 function in the same manner as the first measurement section 20 . Therefore, at least one of the first measurement unit 20 and the second measurement unit 30 should be included in the measurement device 6 or the integration device 24 .

That is, if the measuring device 6 has the first measuring section 20 , the integrating device 24 does not need to have the second measuring section 30 . If the integration device 24 has the second measurement section 30 , the measurement device 6 need not have the first measurement section 20 . Hereinafter, unless otherwise specified, the first measurement unit 20 will be described.

The analysis unit 32 performs speech analysis based on the speech information.

Next, specific operations of the measuring device 6 and the accumulating device 24 will be described. When the speaker 4 speaks, the sound is collected by the sound collecting unit 8 . The generation unit 10 generates audio information based on the collected audio. The first frequency control unit 12 controls the sampling frequency f for generating the audio information based on the volume Vo included in the audio information and the amount of change in the volume Vo.

Specifically, the first frequency control unit 12 roughly divides the volume Vo into a high range, a middle range, and a low range, and controls the sampling frequency f to be higher for the higher range, and to increase the sampling frequency f for the lower range. Control the frequency f to be low. Also, in each range, the sampling frequency f when the amount of change in the volume Vo is positive is set higher than the sampling frequency f when the amount of change in the volume Vo is negative.

Therefore, the power control unit 16 causes the power supply 14 to generate more power as the sampling frequency f is higher, and causes the power supply 14 to generate less power as the sampling frequency f is lower. Also, the more positive the amount of change in the volume Vo is maintained, the higher the sampling frequency f is maintained, the larger the amount of power supplied by the power supply 14, but the more the amount of change in the volume Vo is negative. is maintained, the lower the sampling frequency f is maintained, and the amount of power supplied by the power supply 14 is reduced.

According to this embodiment, the power control unit 16 changes the amount of power supplied by the power supply 14 according to the presence or absence of speech by the speaker 4 or the volume Vo of the speech. Therefore, power is not consumed when the generating unit 10 does not generate audio information. Also, when the power control unit 16 controls the sampling frequency f to be low, the amount of power supplied from the power supply 14 is suppressed. Therefore, the amount of power supplied by the power supply 14 can be suppressed.

Also, the smaller the volume Vo of the voice uttered by the speaker 4 is, or the more negative the amount of change in the volume Vo is maintained, the lower the sampling frequency f can be suppressed. The amount can be further reduced.

Next, an example of the operation of the typical example of the measuring device 6 according to this embodiment will be described with reference to FIG. FIG. 2 is a flow chart showing an example of the operation of a typical example of measurement system 2 and measurement device 6 . As shown in FIG. 2, the process includes steps S10 to S16. The measuring device 6 and the accumulating device 24 execute the processing from step S10 to step S16. Specifically, it is as follows.

As shown in FIG. 2, first, in step S10, the generator 10 generates speech information from the speech of the speaker 4 at a predetermined sampling frequency f. The process proceeds to step S12.

In step S12, the first frequency control unit 12 controls the sampling frequency f for generating the audio information based on the volume Vo included in the audio information and the amount of change in the volume Vo. The process proceeds to step S14.

In step S<b>14 , the power supply 14 supplies power to the generator 10 . The process proceeds to step S16.

In step S16, the power control unit 16 controls the power supply amount based on the sampling frequency f. Then the process ends.

(Concrete example)
Next, a specific example of the measuring device 6 according to this embodiment will be described with reference to FIG. FIG. 3 is a diagram showing a specific example of the measurement system 2 and the measurement device 6. When the horizontal axis represents time t and the vertical axis represents volume Vo, sampling points of volume Vo at time t are connected and derived. 2 shows a graph of the adjusted volume function Vo(t).

In a specific example, as shown in FIG. 3, the volume Vo of the sound collected by the sound collector 8 is controlled by the first frequency control unit 12 using a first threshold value Th1 and a second threshold value Th2. Divided into sound range and low range.

As shown in FIG. 3, in the measuring device 6, the first frequency control unit 12 changes the sampling frequency f to the first sampling frequency f1 when the change amount is positive when the sound volume Vo is equal to or greater than the first threshold value Th1. , and when the amount of change is negative, the sampling frequency f is controlled to a second sampling frequency f2 lower than the first sampling frequency f1.

In other words, when the volume Vo is in the high frequency range equal to or higher than the first threshold Th1 and the volume Vo is increasing, the first frequency control unit 12 samples the volume Vo at the highest first sampling frequency f1. . At this time, the power supply 14 supplies the largest amount of power to the sound collector 8 and the generator 10 .

Further, when the volume Vo is in the high range of the first threshold value Th1 or more and the volume Vo is further decreasing, the first frequency control section 12 samples the volume Vo at the second sampling frequency f2. The second sampling frequency f2 is lower than the first sampling frequency f1.

Next, as shown in FIG. 3, when the volume Vo is less than the first threshold Th1 and equal to or greater than the second threshold Th2, the first frequency control unit 12 sets the sampling frequency f to the first The sampling frequency is controlled to a third sampling frequency f3 lower than the second sampling frequency f2, and when the amount of change is negative, the sampling frequency f is controlled to a fourth sampling frequency f4 lower than the third sampling frequency f3.

That is, when the volume Vo is in the middle range that is less than the first threshold Th1 and equal to or greater than the second threshold Th2, and the volume Vo is increasing, the first frequency control unit 12 reduces the volume Vo at the third sampling frequency f3. to sample. The third sampling frequency f3 is lower than the second sampling frequency f2.

Further, when the volume Vo is in the middle range less than the first threshold Th1 and equal to or greater than the second threshold Th2 and the volume Vo is further decreasing, the first frequency control unit 12 reduces the volume Vo at the fourth sampling frequency f4. to sample. The fourth sampling frequency f4 is lower than the third sampling frequency f3.

When the volume Vo is less than the second threshold Th2, the first frequency control unit 12 controls the sampling frequency f to a fifth sampling frequency f5 lower than the fourth sampling frequency f4 when the amount of change is positive. When the quantity is negative, the sampling frequency f is controlled to a sixth sampling frequency f6 which is lower than the fifth sampling frequency f5.

That is, when the volume Vo is in the low range below the second threshold Th2 and the volume Vo is increasing, the first frequency control section 12 samples the volume Vo at the fifth sampling frequency f5. The fifth sampling frequency f5 is lower than the fourth sampling frequency f4.

Further, when the volume Vo is in the low range below the second threshold Th2 and the volume Vo is further decreasing, the first frequency control unit 12 samples the volume Vo at the lowest sixth sampling frequency f6. .

Next, an example of the operation of a specific example of the measurement system 2 and the measurement device 6 according to this embodiment will be described with reference to FIGS. 4 to 7. FIG. 4 to 7 are flow charts showing an example of the operation of a specific example of the measurement system 2 and the measurement device 6. FIG. As shown in FIGS. 4-7, the process includes steps S20 through S52. The measuring device 6 and the accumulating device 24 execute the processing from step S20 to step S52. Specifically, it is as follows.

First, since steps S20 to S26 shown in FIG. 4 are the same as steps S10 to S16 described in FIG. 2, overlapping descriptions will be omitted.

Next, as shown in FIG. 4, in step S29, the first frequency control section 12 controls the sampling frequency f. The process proceeds to step S30.

In step S30, the first frequency control unit 12 determines whether or not the volume Vo is greater than or equal to the first threshold Th1. If the volume Vo is greater than or equal to the first threshold Th1 (Yes in step S30), the process proceeds to step S32. If the volume Vo is less than the first threshold Th1 (No in step S30), the process proceeds to step S38 shown in FIG.

In the case of Yes in step S32, the first frequency control section 12 determines whether or not the amount of change in the volume Vo is positive. If the amount of change in volume Vo is positive (Yes in step S32), the process proceeds to step S34. If the amount of change in volume Vo is negative (No in step S32), the process proceeds to step S36.

In the case of Yes in step S32, the first frequency control section 12 sets the sampling frequency f to the first sampling frequency f1 in step S34. The process proceeds to step S52 shown in FIG.

If No in step S32, the first frequency control unit 12 sets the sampling frequency f to the second sampling frequency f2 in step S36. The process proceeds to step S52 shown in FIG.

In the case of No in step S30, in step S38 shown in FIG. 5, the first frequency control unit 12 determines whether or not the volume Vo is equal to or greater than the first threshold value Th1. If the volume Vo is greater than or equal to the first threshold Th1 (Yes in step S38), the process proceeds to step S40. If the volume Vo is less than the first threshold Th1 (No in step S32), the process proceeds to step S46 shown in FIG.

In the case of Yes in step S38 shown in FIG. 5, in step S40, the first frequency control unit 12 determines whether or not the amount of change in volume Vo is positive. If the amount of change in volume Vo is positive (Yes in step S40), the process proceeds to step S42. If the amount of change in volume Vo is negative (No in step S40), the process proceeds to step S44.

In the case of Yes in step S40, the first frequency control section 12 sets the sampling frequency f to the third sampling frequency f3 in step S42. The process proceeds to step S52 shown in FIG.

If No in step S40, the first frequency control unit 12 sets the sampling frequency f to the fourth sampling frequency f4 in step S44. The process proceeds to step S52 shown in FIG.

In the case of No in step S38, in step S46 shown in FIG. 6, the first frequency control unit 12 determines whether or not the amount of change in volume Vo is positive. If the amount of change in volume Vo is positive (Yes in step S46), the process proceeds to step S48. If the amount of change in volume Vo is negative (No in step S46), the process proceeds to step S50.

In the case of Yes in step S46 shown in FIG. 6, in step S48, the first frequency control unit 12 sets the sampling frequency f to the fifth sampling frequency f5. The process proceeds to step S52 shown in FIG.

If No in step S46, the first frequency control unit 12 sets the sampling frequency f to the sixth sampling frequency f6 in step S50. The process proceeds to step S52 shown in FIG.

At step S52 shown in FIG. 7, the measuring device 6 or the integrating device 24 determines whether or not to continue the control. If it is determined that the measurement device 6 or the accumulation device 24 continues the control (Yes in step S52), the processing from step S30 shown in FIG. 4 is repeated. If it is determined that the measurement device 6 or the accumulation device 24 does not continue the control (No in step S52), the process ends.

(Modification)
Next, modifications of the measurement system 2 and the measurement device 6 according to the present embodiment will be described with reference to FIGS. 8 to 11. FIG. 8 to 11 are diagrams showing modifications of the measurement system 2 and the measurement device 6. FIG. 8 to 11 show graphs of volume function Vo(t) derived by connecting sampling points of volume Vo at time t, where time t is plotted on the horizontal axis and volume Vo is plotted on the vertical axis.

In a variant, the measuring device 6 comprises a first measuring section 20 for estimating the amount of change. As shown in FIG. 8, the first measurement unit 20 determines that the first sound volume ΔV1 sampled at the first minute time Δt1 is minimal and the first sound volume ΔV1 sampled at the second minute time Δt2 after the first minute time Δt1 When the second volume .DELTA.V2 is greater than the first volume .DELTA.V1 and is extremely small, it is assumed that the volume Vo tends to increase.

That is, as shown in FIG. 8, in a predetermined time range T, the point A of the volume function Vo(t) is the point sampled at the first minute time Δt1, and the volume Vo is the first volume ΔV1. Also, at point A, the first derivative obtained by differentiating the first volume ΔV1 with respect to the minute time Δt is zero, and the second derivative is positive.

Therefore, point A is a minimum point. Also, the first volume ΔV1 is the local minimum value in the time range T and the minimum value.

Further, the volume function Vo(t) rises from point A as indicated by arrow C with the passage of time t, passes through point B after passing through the maximum point once. A point B is a point sampled at the second minute time Δt2, and the volume Vo is the second volume ΔV2. The second volume ΔV2 is greater than the first volume ΔV1. At point B, the first derivative obtained by differentiating the second volume ΔV2 with respect to the minute time Δt is zero, and the second derivative is positive.

In this way, when the minimum points are consecutive at time Δt1 and time Δt2, and the minimum value at time Δt2 is larger than the minimum value at time Δt1, the first measurement unit 20 measures the volume Assume that Vo is on the increase.

Further, as shown in FIG. 9, the first measuring unit 20 determines that the third volume ΔV3 sampled at the third minute time Δt3 is minimal, and the sound volume ΔV3 sampled at the fourth minute time Δt4 after the third minute time Δt3 is When the fourth volume ΔV4 is larger than the third volume ΔV3 and is extremely small, and it is estimated that the volume Vo tends to increase, the fourth volume ΔV4 sampled at the fifth time t5 after the fourth minute time Δt4 When the fifth volume V5 is smaller than the fourth volume .DELTA.V4, it is assumed that the volume Vo changed from an increasing trend to a decreasing trend.

That is, as shown in FIG. 9, in a predetermined time range T, the point D of the volume function Vo(t) is sampled at the third minute time Δt3, and the third volume ΔV3 is the local minimum and minimum value in the time range T. It is a minimum point that takes a value.

After that, the volume function Vo(t) rises from point D as indicated by arrow G as time t elapses, passes through point E after passing through the maximum point once. Point E is sampled at the fourth minute time Δt4 and the fourth volume ΔV4 is greater than the third volume ΔV3. Also, the fourth volume ΔV4 is a minimum point at which the time range T has a minimum value.

In this way, when the minimum points are consecutive at time Δt3 and time Δt4, and the minimum value at time Δt4 is larger than the minimum value at time Δt3, the first measurement unit 20 measures the volume Assume that Vo is on the increase.

Furthermore, after that, the loudness function Vo(t) passes through the point F after passing through the local maximum once. Point F is sampled at a fifth time t5 and the fifth volume V5 is less than the fourth volume ΔV4.

In this way, the minimum points continue at time Δt3 and time Δt4, the minimum value at time Δt4 is larger than the minimum value at time Δt3, and the fifth volume V5 at time t5 is the fourth volume at time Δt4. When the volume is smaller than ΔV4, the first measurement unit 20 estimates that the volume Vo changed from an increasing trend to a decreasing trend in the time range T.

Further, as shown in FIG. 10, the first measuring unit 20 determines that the sixth volume ΔV6 sampled at the sixth minute time Δt6 is maximum and the sound volume ΔV6 sampled at the seventh minute time Δt7 after the sixth minute time Δt6 is the maximum. When the seventh volume ΔV7 is smaller than the sixth volume ΔV6 and is maximum, it is estimated that the volume Vo tends to decrease.

That is, as shown in FIG. 10, in the predetermined time range T, the point I of the volume function Vo(t) is the point sampled at the sixth minute time Δt6, and the volume Vo is the sixth volume ΔV6. At the point I, the first derivative obtained by differentiating the sixth volume ΔV6 with respect to the minute time Δt is zero, and the second derivative is negative.

Therefore, point I is a local maximum. Also, the sixth volume ΔV6 is the local maximum value in the time range T.

Further, the volume function Vo(t) descends from the point I as indicated by the arrow K as the time t elapses, passes through the point J after passing through the minimum point once. A point J is a point sampled at the seventh minute time Δt7, and the volume Vo is the seventh volume ΔV7. The seventh volume ΔV7 is smaller than the sixth volume ΔV6. At the point J, the first derivative obtained by differentiating the seventh volume ΔV7 with respect to the minute time Δt is zero, and the second derivative is negative.

In this way, when the maximum points at time Δt6 and time Δt7 are continuous and the maximum value at time Δt7 is smaller than the maximum value at time Δt6, the first measurement unit 20 measures the volume Assume that Vo is on a decreasing trend.

Further, as shown in FIG. 11, the first measurement unit 20 determines that the eighth sound volume ΔV8 sampled at the eighth minute time Δt8 is maximum and the volume ΔV8 sampled at the ninth minute time Δt9 after the eighth minute time Δt8 is the maximum. The ninth volume ΔV9 sampled at the tenth time t10 after the ninth minute time Δt9, when it is estimated that the volume Vo tends to decrease because the ninth volume ΔV9 is smaller than the eighth volume ΔV8 and is maximum. When the 10th volume V10 is greater than the ninth volume ΔV9, it is assumed that the volume Vo has changed from a decreasing trend to an increasing trend.

That is, as shown in FIG. 11, in a predetermined time range T, the point L of the volume function Vo(t) is sampled at the eighth minute time Δt8, and the eighth volume ΔV8 is the local maximum and the maximum value in the time range T. It is a local maximum point that takes a value.

After that, the volume function Vo(t) descends from the point L as indicated by an arrow P as time t elapses, passes through the point M after passing through the minimum point once. The point M is sampled at the ninth minute time Δt9 and the ninth volume ΔV9 is less than the eighth volume ΔV8. Also, the ninth volume ΔV9 is the maximum value in the time range T.

In this way, when the maximum points at time Δt8 and time Δt9 are consecutive and the maximum value at time Δt9 is smaller than the maximum value at time Δt8, the first measurement unit 20 measures the volume Assume that Vo is on a decreasing trend.

Further, thereafter, the loudness function Vo(t) passes through the point N after passing through the local minimum once. Point N is sampled at tenth time t10, and tenth volume V10 is greater than ninth volume ΔV9.

In this way, the maximum points at time Δt8 and time Δt9 are continuous, and the maximum value at time Δt8 is smaller than the maximum value at time Δt9. When the volume is greater than ΔV9, the first measuring unit 20 estimates that the volume Vo has changed from a decreasing trend to an increasing trend in the time range T. FIG.

The embodiments of the present invention have been described above with reference to the drawings. However, the present invention is not limited to the above-described embodiments, and can be implemented in various aspects without departing from the gist of the present invention. Various inventions can be formed by appropriately combining the plurality of constituent elements disclosed in the above embodiments. For example, some components may be deleted from all components shown in this embodiment. Furthermore, the constituent elements of different embodiments may be combined as appropriate. In order to facilitate understanding, the drawings mainly show each component schematically, and the number of each component shown in the drawing differs from the actual number for the convenience of drawing. Further, the shape and the like of each component shown in the above embodiment is an example and is not particularly limited, and various modifications are possible without substantially departing from the configuration of the present invention.

INDUSTRIAL APPLICABILITY The present invention can be used in the fields of measuring devices, measuring systems, and measuring methods.

2 Measurement system 4 Speaker 6 Measurement device 8 Sound collector 10 Generation unit 12 First frequency control unit 14 Power supply 16 Power control unit 18 First communication unit 20 First measurement unit 22 Communication line 24 Integration device 26 Second communication unit 28 Second frequency control unit 30 Second measurement unit 32 Analysis unit 34 Hub device 36 Server device

Claims (7)

a generator that generates speech information from the speaker's speech at a sampling frequency;
a first frequency control unit that controls the sampling frequency;
a power supply that supplies power to the generator;
a power control unit that controls the amount of power supplied based on the sampling frequency ,
The measuring device, wherein the first frequency control section controls the sampling frequency for generating the audio information based on a volume included in the audio information and an amount of change in the volume. The first frequency control unit is
When the volume is greater than or equal to the first threshold,
controlling the sampling frequency to a first sampling frequency when the amount of change is positive, and controlling the sampling frequency to a second sampling frequency lower than the first sampling frequency when the amount of change is negative;
When the volume is less than the first threshold and greater than or equal to the second threshold,
controlling the sampling frequency to a third sampling frequency lower than the second sampling frequency when the amount of change is positive; and controlling the sampling frequency to a fourth sampling frequency lower than the third sampling frequency when the amount of change is negative. control to
When the volume is less than the second threshold,
controlling the sampling frequency to a fifth sampling frequency lower than the fourth sampling frequency when the amount of change is positive; and controlling the sampling frequency to a sixth sampling frequency lower than the fifth sampling frequency when the amount of change is negative. 2. The measuring device according to claim 1 , which controls to . A first measuring unit for estimating the amount of change,
The first measurement unit is
When the first sound volume sampled in the first minute time is extremely low, and the second sound volume sampled in the second minute time after the first minute time is greater than the first sound volume and extremely low, Presuming that the volume is on the rise,
The third sound volume sampled in the third minute time is minimal, and the fourth sound volume sampled in the fourth minute time after the third minute time is greater than the third minute time and is minimal, When the volume is estimated to be on an increasing trend, when a fifth volume sampled at a fifth time after the fourth minute time is smaller than the fourth volume, the volume tends to decrease from an increasing trend. presumed to have changed
When the sixth volume sampled at the sixth minute time is maximum, and the seventh volume sampled at the seventh minute time after the sixth minute time is smaller than the sixth volume and is maximum, said Presuming that the volume is on a downward trend,
The 8th sound volume sampled at the 8th minute time is maximum, and the 9th sound volume sampled at the 9th minute time after the 8th minute time is smaller than the 8th sound volume and is the maximum, When the volume is presumed to be on a downward trend, and the tenth volume sampled at a tenth time after the ninth minute time is greater than the ninth volume, the volume tends to increase from a decreasing trend. 3. A measuring device according to claim 1 or claim 2 , which assumes conversion. comprising a measuring device and an accumulating device,
The measuring device is
a generator that generates speech information from the speaker's speech at a sampling frequency;
a power supply that supplies power to the generator;
a power control unit that controls the amount of power supplied based on the sampling frequency,
The measurement device or the integration device includes a frequency control unit,
The frequency control unit controls the sampling frequency,
The measurement system, wherein the frequency control unit controls the sampling frequency for generating the audio information based on the volume included in the audio information and the amount of change in the volume. The frequency control unit is
When the volume is greater than or equal to the first threshold,
controlling the sampling frequency to a first sampling frequency when the amount of change is positive, and controlling the sampling frequency to a second sampling frequency lower than the first sampling frequency when the amount of change is negative;
When the volume is less than the first threshold and greater than or equal to the second threshold,
controlling the sampling frequency to a third sampling frequency lower than the second sampling frequency when the amount of change is positive; and controlling the sampling frequency to a fourth sampling frequency lower than the third sampling frequency when the amount of change is negative. control to
When the volume is less than the second threshold,
controlling the sampling frequency to a fifth sampling frequency lower than the fourth sampling frequency when the amount of change is positive; and controlling the sampling frequency to a sixth sampling frequency lower than the fifth sampling frequency when the amount of change is negative. 5. The measurement system according to claim 4 , which controls to . generate speech information from the speaker's speech at the sampling frequency,
controlling the sampling frequency;
supply power,
controlling the power supply amount based on the sampling frequency;
A measurement method comprising: controlling the sampling frequency for generating the audio information based on the volume included in the audio information and the amount of change in the volume. When the volume is greater than or equal to the first threshold,
controlling the sampling frequency to a first sampling frequency when the amount of change is positive, and controlling the sampling frequency to a second sampling frequency lower than the first sampling frequency when the amount of change is negative;
When the volume is less than the first threshold and greater than or equal to the second threshold,
controlling the sampling frequency to a third sampling frequency lower than the second sampling frequency when the amount of change is positive; and controlling the sampling frequency to a fourth sampling frequency lower than the third sampling frequency when the amount of change is negative. control to
When the volume is less than the second threshold,
controlling the sampling frequency to a fifth sampling frequency lower than the fourth sampling frequency when the amount of change is positive; and controlling the sampling frequency to a sixth sampling frequency lower than the fifth sampling frequency when the amount of change is negative. 7. The measuring method according to claim 6 , wherein the control is performed to

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