CN116033083A - Automatic power consumption adjusting method, device and system for single access robot - Google Patents

Abstract

The application provides an automatic power consumption adjusting method, device and system of an access and record single machine robot, which are used for determining the electric quantity condition of the current working state according to the working parameters output by the access and record single machine robot, analyzing the record single line occupying state of the access and record single machine robot according to the condition of the current recorded data, analyzing the data calling state of the access and record single machine robot according to the condition of access equipment, determining the working frequency of the access and record single machine robot according to the electric quantity mode, and simultaneously determining the power consumption level of a data calling link and a data transmission link according to the record single line occupying state and the data calling state respectively, thereby achieving the purposes of prolonging the working time length of the access and record single machine robot and improving the energy consumption utilization rate.

Description

Automatic power consumption adjusting method, device and system for single access robot

Technical Field

The application belongs to the technical field of intelligent robots, and particularly relates to an automatic power consumption adjusting method, device and system for an access and record single robot.

Background

Call centers, also known as customer service centers, originated in the 30 s of the 20 th century, and initially transferred the user's call to answering stations or specialists to provide various telephone response services to the customer. With the increase of transferred calls and answers, an interactive voice response system is established, and the system can realize the response of the common problems of the client part to be responded and processed by a machine 'automatic telephone operator', can process telephone polls from enterprises and customers, particularly has the capability of simultaneously processing a large number of incoming calls, can automatically distribute the incoming calls to personnel with corresponding skills to process, and can record and store all incoming call information.

Currently, interactive voice response systems (call center systems) of call centers are developing rapidly, and various links ingested by intelligent robots are causing a series of problems and challenges of energy consumption. For example, the single-access robot cannot control the size of recorded data according to the residual electric quantity, and cannot automatically reduce power consumption according to the use condition, so that the single-access robot generates high energy consumption, and long-term continuous working conditions not only influence the service life of the single-access robot, but also can increase the fault risks such as abnormal power supply, short circuit and the like.

Disclosure of Invention

In view of this, the present application provides a method, an apparatus and a system for adjusting power consumption of an access and record single robot, which can automatically adjust power consumption output according to the electric quantity state of the access and record single robot.

The specific technical scheme of the application is as follows:

the first aspect of the present application provides a method for adjusting automatic power consumption of a single access robot, comprising the following steps:

after the access signal of the single access robot is identified, the working parameters of the single access robot are acquired, and the electric quantity mode in the current working state is determined according to the working parameters;

acquiring a recording parameter of a recording robot, and determining a recording busy state in a current working state according to the recording parameter;

acquiring equipment parameters of an access list robot, and determining a data calling state in a current working state according to the equipment parameters;

and determining the working frequency of the single-access robot according to the electric quantity mode, controlling the single-access robot to execute data calling work according to the single-access busy state, and controlling the single-access robot to execute data transmission work according to the data calling state.

Further, the working parameter is a working voltage, and the electric quantity mode under the current working state determined according to the working parameter is specifically:

respectively acquiring short-time working voltage, lowest working voltage and highest working voltage of the single access robot;

calculating a first difference voltage according to the short-time working voltage and the lowest working voltage, and calculating a second difference voltage according to the highest working voltage and the short-time working voltage;

and determining an electric quantity mode in the current working state according to the ratio of the second differential voltage to the first differential voltage.

Further, determining the recording busy state in the current working state according to the recording parameters specifically includes:

respectively acquiring low-frequency-band data and high-frequency-band data recorded in a short period by the single access robot, respectively extracting the recording duration, and introducing duration weight to calculate a first recording duration;

respectively acquiring low-frequency band data and high-frequency band data recorded by the access bill robot in a long term, respectively extracting the bill duration, and introducing duration weight to calculate a second bill duration;

and determining the recording busy state in the current working state according to the ratio of the second recording duration to the first recording duration.

Further, the method further comprises the following steps:

judging whether to start to acquire the recording parameters of the single-access robot according to the electric quantity mode of the single-access robot in the current working state, and determining the acquisition range of the recording parameters.

Further, determining the data call state in the current working state according to the equipment parameter is specifically:

identifying a data transmission state in the equipment parameters and the number of the equipment corresponding to the data transmission state;

introducing quantity weight to the quantity of the devices to calculate the quantity of the calling devices, and determining the data calling state in the current working state according to the quantity of the calling devices.

Further, the working frequency of the single robot for access and recording is determined according to the electric quantity mode specifically as follows:

if the electric quantity mode is a normal electric quantity mode, the working frequency is set to be 1;

and if the electric quantity mode is a low electric quantity mode, determining the working frequency according to the electric quantity level in the electric quantity mode.

Further, the method for controlling the record-taking robot to execute data calling work according to the record-taking busy state specifically comprises the following steps:

determining the packing time length of the record data according to the state of the occupied record list;

and controlling the access list robot to execute data calling work according to the parameter limit of the packing time length.

Further, the control of the record stand-alone robot to execute the data transmission work according to the data calling state specifically comprises the following steps:

determining the transmission frequency of the access equipment according to the data calling state;

and controlling the access list robot to limit the execution of data transmission work according to the parameters of the transmission frequency.

The second aspect of the present application provides an automatic power consumption adjusting device of an access and recording single robot, the automatic power consumption adjusting device of the access and recording single robot includes:

the power supply monitoring module is used for starting to acquire the working parameters of the single-access robot after the access signal of the single-access robot is identified, and determining the electric quantity mode in the current working state according to the working parameters;

the recording analysis module is used for acquiring recording parameters of the access recording robot and determining the recording busy state in the current working state according to the recording parameters;

the device analysis module is used for acquiring device parameters of the single access robot and determining a data calling state in the current working state according to the device parameters;

and the state control module is used for determining the working frequency of the single-access robot according to the electric quantity mode, controlling the single-access robot to execute data calling work according to the single-access busy state, and controlling the single-access robot to execute data transmission work according to the data calling state.

A third aspect of the present application provides an intelligent call center system, where the intelligent call center system includes each module in the access ticket robot automatic power consumption adjustment device.

In summary, the application provides a method, a device and a system for adjusting automatic power consumption of an access and record single robot, which are used for determining the electric quantity condition of the current working state according to the working parameters output by the access and record single robot, analyzing the record single busy state of the access and record single robot according to the condition of the current recorded data, analyzing the data calling state of the access and record single robot according to the condition of access equipment, determining the working frequency of the access and record single robot according to the electric quantity mode, and simultaneously determining the power consumption level of a data calling link and a data transmission link according to the record single busy state and the data calling state respectively, thereby achieving the purposes of prolonging the working time of the access and record single robot and improving the energy consumption utilization rate.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive faculty for a person skilled in the art.

FIG. 1 is a flow chart of a method for adjusting automatic power consumption of a single access robot;

fig. 2 is a block diagram of an automatic power consumption adjusting device of a single access robot of the present application.

Detailed Description

For the purposes of making the objects, features, and advantages of the present application more apparent and understandable, the technical solutions in the embodiments of the present application are clearly and completely described, and it is apparent that the embodiments described below are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art without undue burden from the present disclosure, are within the scope of the present disclosure.

Referring to fig. 1, fig. 1 is a flowchart of a method for adjusting automatic power consumption of a single robot.

The embodiment of the application provides an automatic power consumption adjusting method of an access and recording single robot, which comprises the following steps:

s1: after the access signal of the single access robot is identified, the working parameters of the single access robot are acquired, and the electric quantity mode in the current working state is determined according to the working parameters;

s2: acquiring a recording parameter of a recording robot, and determining a recording busy state in a current working state according to the recording parameter;

s3: acquiring equipment parameters of an access list robot, and determining a data calling state in a current working state according to the equipment parameters;

s4: and determining the working frequency of the single-access robot according to the electric quantity mode, controlling the single-access robot to execute data calling work according to the single-access busy state, and controlling the single-access robot to execute data transmission work according to the data calling state.

As an embodiment, the working parameters of the single access robot in S1 may be working voltage, working power, etc., which may be obtained by testing the components such as the voltage sensor. And determining the electric quantity condition of the current working state according to the working parameters output by the single access robot, for example, determining an electric quantity mode by comparing the ratio of the current working voltage to the rated voltage, wherein the ratio exceeds a threshold value to determine a normal electric quantity mode, and the ratio is lower than the threshold value to determine a low electric quantity mode, thereby being used as a basis for controlling the power consumption adjustment range.

As an embodiment, the recording parameters of the recording robot in S2 refer to the data amount and duration of the recorded data, and may be tested by a decoder or other device. And analyzing the recording busy state of the single access robot, such as high busy state or low busy state, and the like, according to the current recorded data condition, and taking the recording busy state as a reference for automatic power consumption adjustment.

As an embodiment, the device parameters of the access ticket robot in S3 refer to data transmission attributes, number, etc. of terminal devices of the access ticket robot, such as a communication device and a display. The data calling state of the single access robot is analyzed according to the condition of the access equipment, and the data calling state can be used as a reference for automatic power consumption adjustment.

As an embodiment, in S4, the working frequency of the single-access robot is determined according to the electric quantity mode, the packaging time length, the data packet capacity and the like of the single-access data are determined according to the single-access busy state, so that the power consumption level of the data calling link is limited, and meanwhile, the transmission frequency, the starting frequency and the like of the access equipment are determined according to the data calling state, so that the power consumption level of the data transmission link is limited, and finally, the purposes of prolonging the working time length of the single-access robot and improving the energy consumption utilization rate are achieved.

According to the embodiment of the application, the working parameter is a working voltage, and the electric quantity mode under the current working state according to the working parameter is specifically:

respectively acquiring short-time working voltage, lowest working voltage and highest working voltage of the single access robot;

calculating a first difference voltage according to the short-time working voltage and the lowest working voltage, and calculating a second difference voltage according to the highest working voltage and the short-time working voltage;

and determining an electric quantity mode in the current working state according to the ratio of the second differential voltage to the first differential voltage.

As an example, the short-term operating voltage may be a voltage value of approximately 1s, and the minimum operating voltage and the maximum operating voltage may be determined by hardware configuration information. The first differential voltage and the second differential voltage reflect the approaching degree of the current output voltage and the limiting voltage, and the activity of the current output voltage can be analyzed by comparing the first differential voltage with the second differential voltage, so that the residual electric quantity condition is determined. For example, when the ratio is equal to or greater than one-half, the normal power remaining mode is set; a low power remaining mode when the ratio is less than one-half; and when the ratio is less than one third, the power supply is in an ultralow power remaining mode.

According to the embodiment of the application, the recording busy state under the current working state is determined according to the recording parameters specifically as follows:

respectively acquiring low-frequency-band data and high-frequency-band data recorded in a short period by the single access robot, respectively extracting the recording duration, and introducing duration weight to calculate a first recording duration;

respectively acquiring low-frequency band data and high-frequency band data recorded by the access bill robot in a long term, respectively extracting the bill duration, and introducing duration weight to calculate a second bill duration;

and determining the recording busy state in the current working state according to the ratio of the second recording duration to the first recording duration.

As one example, the acquisition range of the low-frequency band data and the high-frequency band data can be determined according to the history data of the contact list, for example, the low-frequency band is 24bit 48khz, and the high-frequency band is 24bit 96khz. The short-term duration may be set to 1h and the long-term duration may be set to one month. After extracting the duration of the form, because the duty conditions of the low-frequency band data and the high-frequency band data are unbalanced, a duration weight needs to be introduced so as to accurately evaluate the total duration of the form, wherein the duration weight of the low-frequency band data can be set to be 1, and the duration weight of the high-frequency band data can be set to be 2. The first recording duration is the sum of the recording durations of the low-frequency band data and the high-frequency band data recorded in a short period, and the second recording duration is the ratio of the sum of the recording durations of the low-frequency band data and the high-frequency band data recorded in a long period to the corresponding unit time (such as 720 h). The comparison result of the second recording duration and the first recording duration can reflect the workload level of the current recording data, so that the recording busy state is determined. For example, a high duty recording state is set when the ratio is greater than 200%; and setting the medium duty recording state when the ratio is less than or equal to 200% and greater than 50%, and setting the low duty recording state when the wallpaper is less than or equal to 50%.

According to an embodiment of the present application, further comprising:

judging whether to start to acquire the recording parameters of the single-access robot according to the electric quantity mode of the single-access robot in the current working state, and determining the acquisition range of the recording parameters.

As an embodiment, if the recording parameter is selected according to the current power level, the automatic power consumption adjustment process may be stopped to ensure the normal working efficiency when the power is sufficient, such as a sufficient power mode with a power exceeding 80%, and the automatic power consumption adjustment may be performed to extend the working time when the power is low, such as a power mode with a power below 80%. Meanwhile, the acquisition range of the recording parameters can be determined according to the electric quantity level, for example, the low frequency band is set to be 24bit 48khz in the normal electric quantity residual mode, and the high frequency band is set to be 24bit 96khz; setting a low frequency band as 37bit 48khz in a low power remaining mode, and setting a high frequency band as 37bit 96khz; the low frequency band is set to be 50bit 48khz in the ultralow electricity residual mode, and the high frequency band is set to be 50bit 96khz.

According to the embodiment of the application, the data calling state under the current working state is determined according to the equipment parameters specifically as follows:

identifying a data transmission state in the equipment parameters and the number of the equipment corresponding to the data transmission state;

introducing quantity weight to the quantity of the devices to calculate the quantity of the calling devices, and determining the data calling state in the current working state according to the quantity of the calling devices.

As an embodiment, the device parameter is information of the access device, including a device attribute and a data transmission status, etc. The data transmission state is determined according to the size of the call data and the equipment attribute, and can be set to 3 types, wherein the state 1 is a connection data unused state, the state 2 is a connection data low-use state, and the state 3 is a connection data high-use state. And respectively counting the number of access devices in each data transmission state, respectively introducing a number weight into the number of devices in each state, calculating the sum of the number of the devices to obtain the number of calling devices, and balancing the problem of uneven occupancy rate of each device, wherein the analysis of the current data calling state is more accurate, if the number weight of the state 2 and the state 3 is 2, and the number weight of the state 1 is 1. For example, the high call mode is determined when the number of call devices is greater than 15; when the number of calling devices is less than or equal to 15, judging that the calling device is in a medium calling mode; and when the number of calling devices is less than or equal to 5, determining that the calling device is in a low calling mode.

According to the embodiment of the application, the working frequency of the single access robot is determined according to the electric quantity mode, and is specifically as follows:

if the electric quantity mode is a normal electric quantity mode, the working frequency is set to be 1;

and if the electric quantity mode is a low electric quantity mode, determining the working frequency according to the electric quantity level in the electric quantity mode.

As an embodiment, the working frequency of the contact recording robot is not adjusted in the normal power mode, i.e. the working state of the contact recording robot is kept in a full period. The working frequency can be set to be 0.5 in the low power mode, namely, the recording is stopped for 1min and then the recording is started for 1min, and the working frequency can be set to be 0.3 in the ultra-low power mode, namely, the recording is stopped for 2min and then the recording is started for 1min.

According to the embodiment of the application, the method for controlling the record-taking robot to execute data calling work according to the record-taking busy state comprises the following steps:

determining the packing time length of the record data according to the state of the occupied record list;

and controlling the access list robot to execute data calling work according to the parameter limit of the packing time length.

As an embodiment, the loading degree of the record data is determined by the degree of the busy state of the record data, so that the power output is controlled by controlling the calling efficiency of the record data. For example, if the low power mode is determined, the intelligent call center system packs the 5min recording data and records the data by the single access robot in the low recording busy state, packs the 4min recording data and records the data by the single access robot in the medium recording busy state, and packs the 3min recording data and records the data by the single access robot in the high recording busy state. If the ultra-low power mode is determined, the packing time periods in the three states can be respectively adjusted to be 3min, 2min and 1min.

According to the embodiment of the application, the control of the access list robot to execute the data transmission work according to the data calling state specifically comprises the following steps:

determining the transmission frequency of the access equipment according to the data calling state;

and controlling the access list robot to limit the execution of data transmission work according to the parameters of the transmission frequency.

As an embodiment, the throughput of the transmission channel of the recording sheet data is determined by the degree of the data calling state, so that the power output is controlled by controlling the transmission efficiency of the recording sheet data. For example, if the low power mode is determined, the intelligent call center system disconnects the access device with the device state 1 of the access ticket robot after 2min in the low data call state, and other access devices normally operate; the intelligent call center system disconnects the access equipment with the equipment state of 1 of the access bill robot after 2min in the medium data calling state, the transmission frequency of the access equipment with the equipment state of 2 is reduced by 20%, and the transmission frequency of the access equipment with the equipment state of 3 is reduced by 10%; and under the high data call state, the intelligent call center system is disconnected after the access equipment with the equipment state of 1 of the robot is accessed for 2min, the transmission frequency of the access equipment with the equipment state of 2 is reduced by 40%, and the transmission frequency of the access equipment with the equipment state of 3 is reduced by 20%. If the power supply is in the ultra-low power mode, the access equipment with the equipment state of 1 can be disconnected after being set to be 1min in the low data call state, and the transmission frequency of the access equipment with the equipment state of 2 is reduced by 25%; the access equipment with the equipment state 1 can be set to be disconnected immediately in the medium data calling state, the transmission frequency of the access equipment with the equipment state 2 is reduced by 50%, and the transmission frequency of the equipment with the equipment state 3 is reduced by 25%; in the high data call state, the access device with the device state 1 can be set to be disconnected immediately, the transmission frequency of the access device with the device state 2 is reduced by 75%, and the transmission frequency of the access device with the device state 3 is reduced by 50%.

Referring to fig. 2, fig. 2 is a block diagram of an automatic power consumption adjusting device of a single access robot of the present application.

The embodiment of the application also provides an automatic power consumption adjusting device of the single-machine accessing robot, the automatic power consumption adjusting device of the single-machine accessing robot comprises:

the power supply monitoring module 1 is used for starting to acquire the working parameters of the single-access robot after the access signal of the single-access robot is identified, and determining the electric quantity mode in the current working state according to the working parameters;

the recording analysis module 2 is used for acquiring recording parameters of the access recording robot and determining the recording busy state in the current working state according to the recording parameters;

the device analysis module 3 is used for acquiring device parameters of the single access robot and determining a data calling state in the current working state according to the device parameters;

the state control module 4 is used for determining the working frequency of the single-access robot according to the electric quantity mode, controlling the single-access robot to execute data calling work according to the single-access busy state, and controlling the single-access robot to execute data transmission work according to the data calling state.

According to an embodiment of the present application, the operating parameter is an operating voltage, and the power monitoring module is specifically configured to:

respectively acquiring short-time working voltage, lowest working voltage and highest working voltage of the single access robot;

calculating a first difference voltage according to the short-time working voltage and the lowest working voltage, and calculating a second difference voltage according to the highest working voltage and the short-time working voltage;

and determining an electric quantity mode in the current working state according to the ratio of the second differential voltage to the first differential voltage.

According to the embodiment of the application, the recording analysis module is specifically configured to:

respectively acquiring low-frequency-band data and high-frequency-band data recorded in a short period by the single access robot, respectively extracting the recording duration, and introducing duration weight to calculate a first recording duration;

respectively acquiring low-frequency band data and high-frequency band data recorded by the access bill robot in a long term, respectively extracting the bill duration, and introducing duration weight to calculate a second bill duration;

and determining the recording busy state in the current working state according to the ratio of the second recording duration to the first recording duration.

According to an embodiment of the present application, the recording analysis module is further configured to:

judging whether to start to acquire the recording parameters of the single-access robot according to the electric quantity mode of the single-access robot in the current working state, and determining the acquisition range of the recording parameters.

According to an embodiment of the present application, the device analysis module is specifically configured to:

identifying a data transmission state in the equipment parameters and the number of the equipment corresponding to the data transmission state;

introducing quantity weight to the quantity of the devices to calculate the quantity of the calling devices, and determining the data calling state in the current working state according to the quantity of the calling devices.

According to an embodiment of the present application, the state control module is specifically configured to:

if the electric quantity mode is a normal electric quantity mode, the working frequency is set to be 1;

and if the electric quantity mode is a low electric quantity mode, determining the working frequency according to the electric quantity level in the electric quantity mode.

According to an embodiment of the present application, the state control module is specifically configured to:

determining the packing time length of the record data according to the state of the occupied record list;

and controlling the access list robot to execute data calling work according to the parameter limit of the packing time length.

According to an embodiment of the present application, the state control module is specifically configured to:

determining the transmission frequency of the access equipment according to the data calling state;

and controlling the access list robot to limit the execution of data transmission work according to the parameters of the transmission frequency.

The embodiment of the application also provides an intelligent call center system which comprises the modules in the automatic power consumption adjusting device of the access and recording robot.

The above embodiments are merely for illustrating the technical solution of the present application, and not for limiting the same; although the present application has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the corresponding technical solutions.

Claims (10)

1. The automatic power consumption adjusting method for the single access robot is characterized by comprising the following steps of:

after the access signal of the single access robot is identified, the working parameters of the single access robot are acquired, and the electric quantity mode in the current working state is determined according to the working parameters;

acquiring a recording parameter of a recording robot, and determining a recording busy state in a current working state according to the recording parameter;

acquiring equipment parameters of an access list robot, and determining a data calling state in a current working state according to the equipment parameters;

and determining the working frequency of the single-access robot according to the electric quantity mode, controlling the single-access robot to execute data calling work according to the single-access busy state, and controlling the single-access robot to execute data transmission work according to the data calling state.

2. The method for adjusting automatic power consumption of an access and recording robot according to claim 1, wherein the working parameter is a working voltage, and the determining the electric quantity mode in the current working state according to the working parameter is specifically as follows:

respectively acquiring short-time working voltage, lowest working voltage and highest working voltage of the single access robot;

calculating a first difference voltage according to the short-time working voltage and the lowest working voltage, and calculating a second difference voltage according to the highest working voltage and the short-time working voltage;

and determining an electric quantity mode in the current working state according to the ratio of the second differential voltage to the first differential voltage.

3. The method for adjusting automatic power consumption of an access and recording robot according to claim 1, wherein determining a recording busy state in a current working state according to the recording parameter is specifically as follows:

respectively acquiring low-frequency-band data and high-frequency-band data recorded in a short period by the single access robot, respectively extracting the recording duration, and introducing duration weight to calculate a first recording duration;

respectively acquiring low-frequency band data and high-frequency band data recorded by the access bill robot in a long term, respectively extracting the bill duration, and introducing duration weight to calculate a second bill duration;

and determining the recording busy state in the current working state according to the ratio of the second recording duration to the first recording duration.

4. The method for adjusting automatic power consumption of an access single robot as claimed in claim 1, further comprising:

judging whether to start to acquire the recording parameters of the single-access robot according to the electric quantity mode of the single-access robot in the current working state, and determining the acquisition range of the recording parameters.

5. The method for adjusting the automatic power consumption of an access and recording robot according to claim 1, wherein the determining the data calling state in the current working state according to the device parameter is specifically:

identifying a data transmission state in the equipment parameters and the number of the equipment corresponding to the data transmission state;

introducing quantity weight to the quantity of the devices to calculate the quantity of the calling devices, and determining the data calling state in the current working state according to the quantity of the calling devices.

6. The method for adjusting the automatic power consumption of an access and record single robot according to claim 1, wherein the determining the working frequency of the access and record single robot according to the electric quantity mode is specifically as follows:

if the electric quantity mode is a normal electric quantity mode, the working frequency is set to be 1;

and if the electric quantity mode is a low electric quantity mode, determining the working frequency according to the electric quantity level in the electric quantity mode.

7. The method for adjusting the automatic power consumption of an access single robot according to claim 1, wherein the step of controlling the access single robot to execute data calling according to the state of the access single is specifically:

determining the packing time length of the record data according to the state of the occupied record list;

and controlling the access list robot to execute data calling work according to the parameter limit of the packing time length.

8. The method for adjusting the automatic power consumption of an access and record single machine robot according to claim 1, wherein the step of controlling the access and record single machine robot to execute data transmission according to the data calling state is specifically:

determining the transmission frequency of the access equipment according to the data calling state;

and controlling the access list robot to limit the execution of data transmission work according to the parameters of the transmission frequency.

9. The automatic power consumption adjusting device of the single-machine accessing robot is characterized by comprising:

the power supply monitoring module is used for starting to acquire the working parameters of the single-access robot after the access signal of the single-access robot is identified, and determining the electric quantity mode in the current working state according to the working parameters;

the recording analysis module is used for acquiring recording parameters of the access recording robot and determining the recording busy state in the current working state according to the recording parameters;

the device analysis module is used for acquiring device parameters of the single access robot and determining a data calling state in the current working state according to the device parameters;

and the state control module is used for determining the working frequency of the single-access robot according to the electric quantity mode, controlling the single-access robot to execute data calling work according to the single-access busy state, and controlling the single-access robot to execute data transmission work according to the data calling state.

10. An intelligent call center system, comprising the modules of the automatic power consumption adjusting device of the single-access robot of claim 9.

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