Cooperative test system, test method, electronic device, and storage medium

Abstract

The application provides a cooperative test system, a test method, an electronic device and a storage medium, and relates to the technical field of live broadcast machines. The system comprises: an upper computer which is electrically connected with a temperature-adjustable box, a temperature sensor, an audio collector and a device to be tested; the device to be tested, the temperature sensor and the audio collector are placed in the temperature-adjustable box; the device to be tested comprises: a main control chip and a cooling fan; the temperature sensor is used for acquiring the running temperature of the main control chip and sending the running temperature to the upper computer; the upper computer is further used for sending a control signal to the cooling fan to control the cooling fan to enter a working state if the running temperature meets a preset control condition; the audio collector is used for acquiring audio data in the working state of the cooling fan and sending the audio data to the upper computer; and the upper computer is used for determining the audio quality of the device to be tested according to the audio data. The application solves the problem that the traditional domain test cannot cover real working conditions, and significantly improves the test accuracy of the audio quality.

Description

Technical Field

[0001] This application relates to the field of live streaming equipment technology, and more specifically, to a collaborative testing system, testing method, electronic device, and storage medium. Background Technology

[0002] With the widespread adoption of live streaming equipment and the rapid development of audio technology, users' demands for live streaming audio quality are increasing. In the R&D and testing phase of live streaming equipment, existing technologies typically employ a domain-separated testing method: audio quality is tested using temperature-controlled equipment in a standard anechoic chamber for quantitative evaluation. While this separate testing method can independently verify different functions, it neglects the coupled impact of cooling fan noise on audio quality in real-world usage scenarios. Summary of the Invention

[0003] In view of this, the purpose of this application is to overcome the shortcomings of the prior art and provide a collaborative testing system, testing method, electronic device, and storage medium. This application provides the following technical solution: In a first aspect, this application provides a collaborative testing system, the system comprising: an adjustable temperature chamber, a host computer, a temperature sensor, and an audio acquisition device, wherein the host computer is electrically connected to the adjustable temperature chamber, the temperature sensor, the audio acquisition device, and the device under test; The device under test, the temperature sensor, and the audio acquisition device are all placed inside the adjustable temperature chamber. The device under test includes a main control chip and a cooling fan. The temperature sensor is attached to the surface of the main control chip, and the audio acquisition device faces the air outlet of the cooling fan. The temperature sensor is used to acquire the operating temperature of the main control chip and send the operating temperature to the host computer. The operating temperature is positively correlated with the target operating load of the main control chip and the target temperature inside the adjustable temperature chamber. The host computer is also used to determine whether the operating temperature meets the preset control conditions. If it does, it sends a control signal to the cooling fan to control the cooling fan to enter the working state. The audio acquisition device is used to acquire audio data when the device under test plays a preset audio while the cooling fan is in operation, and to send the audio data to the host computer. The host computer is used to determine the audio quality of the device under test based on the audio data.

[0004] In one embodiment, the control signal includes: a temperature-priority control signal, an audio-priority control signal, or a smoothing control signal; the operating state includes: a temperature-priority state, an audio-priority state, or a smoothing state; and sending the control signal to the cooling fan to control the cooling fan to enter the operating state includes: Send the temperature priority control signal to the cooling fan to control the cooling fan to enter the temperature priority state; The audio data includes: first audio data; the step of acquiring audio data when the cooling fan is in operation and the device under test plays a preset audio, and sending the audio data to the host computer, includes: The system acquires first audio data when the device under test plays a preset audio while the cooling fan is in temperature-priority mode, and sends the first audio data to the host computer. Determining the audio quality of the device under test based on the audio data includes: The first audio quality of the device under test is determined based on the first audio data.

[0005] In one embodiment, sending a control signal to the cooling fan to control the cooling fan to enter the working state includes: Send the audio priority control signal to the cooling fan to control the cooling fan to enter the audio priority state; The audio data includes: second audio data, wherein acquiring the audio data when the cooling fan is in operation and the device under test plays a preset audio, and sending the audio data to the host computer includes: The system acquires second audio data when the device under test plays a preset audio in the audio priority state, and sends the second audio data to the host computer. Determining the audio quality of the device under test based on the audio data includes: The second audio quality of the device under test is determined based on the second audio data.

[0006] In one embodiment, sending a control signal to the cooling fan to control the cooling fan to enter the working state includes: Send the smoothing control signal to the cooling fan to control the cooling fan to enter the smoothing state; The audio data includes: third audio data, wherein acquiring the audio data when the cooling fan is in the target operating state and the device under test plays a preset audio, and sending the audio data to the host computer includes: Acquire third audio data when the device under test plays a preset audio in the smooth state of the cooling fan, and send the third audio data to the host computer. Determining the audio quality of the device under test based on the audio data includes: The third audio quality of the device under test is determined based on the third audio data.

[0007] In one embodiment, the host computer is further configured to compare the first audio quality, the second audio quality, and the third audio quality, and determine the optimal audio quality from among the first audio quality, the second audio quality, and the third audio quality; The optimal control strategy for the cooling fan is determined based on the optimal audio quality. Under the optimal control strategy, the host computer sends a target control signal to the cooling fan to control the cooling fan to enter the target working state. Under the target working state, the quality of the audio data acquired by the audio collector is the optimal audio quality.

[0008] In one embodiment, determining whether the operating temperature meets preset control conditions includes: Determine whether the operating temperature is greater than a preset temperature threshold. If it is, determine that the operating temperature meets the preset control conditions.

[0009] In one embodiment, before obtaining the operating temperature of the main control chip, the host computer is further configured to send a preset operating script to the main control chip to adjust the operating load of the main control chip to a target operating load. A temperature control signal is sent to the adjustable temperature chamber to control the temperature inside the adjustable temperature chamber to be adjusted to the target temperature.

[0010] Secondly, this application provides a collaborative testing method applied to the collaborative testing system described in the first aspect, the method comprising: The temperature sensor acquires the operating temperature of the main control chip and sends the operating temperature to the host computer. The operating temperature is positively correlated with the target operating load of the main control chip and the target temperature inside the adjustable temperature chamber. The host computer determines whether the operating temperature meets the preset control conditions. If it does, it sends a control signal to the cooling fan to control the cooling fan to enter the working state. The audio acquisition device acquires audio data when the device under test plays a preset audio while the cooling fan is in operation, and sends the audio data to the host computer. The host computer determines the audio quality of the device under test based on the audio data. Thirdly, this application provides an electronic device, including a memory and a processor, wherein the memory stores a computer program, and the computer program executes the collaborative testing method described in the second aspect when running on the processor.

[0011] Fourthly, this application provides a computer-readable storage medium storing a computer program that, when executed by a processor, implements the collaborative testing method described in the second aspect.

[0012] The collaborative testing system, testing method, electronic device, and storage medium provided in this application include a testing system comprising: an adjustable temperature chamber, a host computer, a temperature sensor, and an audio acquisition device. The host computer is electrically connected to the adjustable temperature chamber, the temperature sensor, the audio acquisition device, and the device under test (DUT). The DUT, the temperature sensor, and the audio acquisition device are all placed inside the adjustable temperature chamber. The DUT includes: a main control chip and a cooling fan. The temperature sensor is attached to the surface of the main control chip, and the audio acquisition device faces the air outlet of the cooling fan. The temperature sensor is used to acquire the temperature of the main control chip. The operating temperature is sent to the host computer. The operating temperature is positively correlated with both the target operating load of the main control chip and the target temperature within the adjustable temperature chamber. The host computer also determines whether the operating temperature meets preset control conditions. If so, it sends a control signal to the cooling fan to activate the cooling fan. The audio acquisition device acquires audio data when the device under test (DUT) plays a preset audio signal while the cooling fan is operating, and sends this audio data to the host computer. The host computer determines the audio quality of the DUT based on the audio data. This application, through integrated collaborative testing, reproduces the coupled influence of ambient temperature, cooling fan noise, and main control chip operating load on audio quality in the actual use scenario of the DUT, solving the problem that traditional domain-specific testing cannot cover real-world operating conditions and significantly improving the accuracy of audio quality testing.

[0013] To make the above-mentioned objectives, features and advantages of this application more apparent and understandable, preferred embodiments are described below in detail with reference to the accompanying drawings. Attached Figure Description

[0014] To more clearly illustrate the technical solutions of the embodiments of this application, the accompanying drawings used in the embodiments will be briefly introduced below. It should be understood that the following drawings only show some embodiments of this application and should not be regarded as a limitation of the scope. For those skilled in the art, other related drawings can be obtained based on these drawings without creative effort.

[0015] Figure 1 A schematic diagram of the collaborative testing system provided in an embodiment of this application is shown; Figure 2 A flowchart of the collaborative testing method provided in an embodiment of this application is shown; Figure 3 A schematic diagram of the structure of an electronic device provided in an embodiment of this application is shown.

[0016] Explanation of key component symbols: 100 - Collaborative testing system; 110 - Adjustable temperature chamber; 120 - Host computer; 130 - Temperature sensor; 140 - Audio acquisition device; 200 - Device under test; 300 - Electronic equipment; 301 - Transceiver; 302 - Processor; 303 - Memory. Detailed Implementation

[0017] The embodiments of this application are described in detail below. Examples of these embodiments are shown in the accompanying drawings, wherein the same or similar reference numerals denote the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the accompanying drawings are exemplary and are only used to explain this application, and should not be construed as limiting this application.

[0018] Furthermore, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of this application, "multiple" means two or more, unless otherwise explicitly specified.

[0019] Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used herein in the template description is for the purpose of describing particular embodiments only and is not intended to be limiting of this application. The term "and / or" as used herein includes any and all combinations of one or more of the associated listed items.

[0020] Example 1 Live streaming equipment typically integrates audio processing functions such as AI noise reduction, automatic gain control, and sound source localization. During use, these functions consume significant computing resources, causing the processing chip to heat up. This triggers the cooling fan to operate at increased speed, interfering with microphone pickup and severely degrading the final audio output quality. Currently, audio performance testing and thermal performance testing are usually conducted independently by different teams in different environments. While this separate testing method can independently verify different functions, it ignores the coupled impact of cooling fan noise on audio quality in real-world usage scenarios. For further information, please refer to [link to relevant documentation / reference]. Figure 1 This application provides a collaborative testing system 100, including: an adjustable temperature chamber 110, a host computer 120, a temperature sensor 130, and an audio acquisition device 140. The host computer 120 is electrically connected to the adjustable temperature chamber 110, the temperature sensor 130, the audio acquisition device 140, and the device under test 200. The device under test 200, the temperature sensor 130, and the audio acquisition device 140 are all placed inside the adjustable temperature chamber 110. The device under test 200 includes a main control chip and a cooling fan. The temperature sensor 130 is attached to the surface of the main control chip, and the audio acquisition device 140 faces the air outlet of the cooling fan. The temperature sensor 130 is used to acquire the operating temperature of the main control chip and send the operating temperature to the host computer 120. The operating temperature is positively correlated with the target operating load of the main control chip and the target temperature in the adjustable temperature chamber 110. The host computer 120 is also used to determine whether the operating temperature meets the preset control conditions. If it does, it sends a control signal to the cooling fan to control the cooling fan to enter the working state. The audio acquisition unit 140 is used to acquire audio data when the device under test 200 plays a preset audio while the cooling fan is in operation, and send the audio data to the host computer 120. The host computer 120 is used to determine the audio quality of the device under test 200 based on the audio data.

[0021] The device under test 200 is placed inside the adjustable temperature chamber 110. The device under test 200 includes a main control chip. Before acquiring the operating temperature of the main control chip, the host computer 120 is also used to send a preset operating script to the main control chip to adjust the operating load of the main control chip to the target operating load; and to send a temperature control signal to the adjustable temperature chamber 110 to control the temperature inside the adjustable temperature chamber 110 to adjust to the target temperature.

[0022] Understandably, during testing, the tester adjusts the temperature inside the adjustable temperature chamber 110 via the host computer 120 according to actual testing needs. For example, when testing the audio quality of the device under test 200 during operation at room temperature, the temperature inside the adjustable temperature chamber 110 is adjusted to 25℃. Simultaneously, the main control chip runs a preset operating script. The operating temperature obtained by the temperature sensor 130 is positively correlated with the target operating load when the main control chip runs the load simulation script and the target temperature inside the adjustable temperature chamber 110.

[0023] The host computer 120 determines whether the operating temperature is greater than the preset temperature threshold. If it is greater, it determines that the operating temperature meets the preset control conditions. At this time, the host computer 120 sends a control signal to the cooling fan to control the cooling fan to enter the working state and simulate the high heat state of the device under test 200 when it is working. At this time, the audio data of the device under test 200 when playing the preset audio is collected by the audio acquisition device 140, thereby determining the audio quality of the device under test 200 during the heat dissipation process.

[0024] In one embodiment, the control signal includes a temperature-priority control signal, an audio-priority control signal, or a smoothing control signal; the operating state includes a temperature-priority state, an audio-priority state, or a smoothing state; and sending a control signal to the cooling fan to control the cooling fan to enter the operating state includes sending the temperature-priority control signal to the cooling fan to control the cooling fan to enter the temperature-priority state. The audio data includes: first audio data. The step of acquiring the audio data when the cooling fan is in working state and the device under test 200 plays a preset audio, and sending the audio data to the host computer 120 includes: acquiring the first audio data when the cooling fan is in temperature priority state and the device under test 200 plays a preset audio, and sending the first audio data to the host computer 120. Determining the audio quality of the device under test 200 based on the audio data includes: determining the first audio quality of the device under test 200 based on the first audio data.

[0025] In one embodiment, sending a control signal to the cooling fan to control the cooling fan to enter the working state includes: sending the audio priority control signal to the cooling fan to control the cooling fan to enter the audio priority state; The audio data includes: second audio data. The step of acquiring the audio data when the cooling fan is in working state and the device under test 200 plays a preset audio, and sending the audio data to the host computer 120 includes: acquiring the second audio data when the cooling fan is in the audio priority state and the device under test 200 plays a preset audio, and sending the second audio data to the host computer 120. Determining the audio quality of the device under test 200 based on the audio data includes: determining the second audio quality of the device under test 200 based on the second audio data.

[0026] In one embodiment, sending a control signal to the cooling fan to control the cooling fan to enter the working state includes: sending the smoothing control signal to the cooling fan to control the cooling fan to enter the smoothing state; The audio data includes: third audio data. The step of acquiring the audio data when the cooling fan plays the preset audio in the target working state and sending the audio data to the host computer 120 includes: acquiring the third audio data when the cooling fan plays the preset audio in the smooth state and sending the third audio data to the host computer 120. Determining the audio quality of the device under test 200 based on the audio data includes: determining the third audio quality of the device under test 200 based on the third audio data.

[0027] In this embodiment, when it is determined that the operating temperature is greater than the preset temperature threshold, that is, the preset control conditions are met, the host computer 120 can send corresponding control signals to the cooling fan according to different test and verification requirements. Specifically, these include: temperature priority control signal, audio priority control signal, or smooth control signal. Different control signals drive the cooling fan into different working states.

[0028] When a temperature-priority control signal is received, the cooling fan prioritizes temperature protection, operating at full speed once the preset temperature threshold is reached, entering temperature-priority mode. When an audio-priority control signal is received, the cooling fan prioritizes human voice pickup quality, dynamically adjusting its speed based on human voice detection results in the audio data. It automatically limits the maximum speed when human voice is detected, entering audio-priority mode. When a smoothing control signal is received, the cooling fan's speed is continuously and dynamically adjusted smoothly based on temperature and audio data, balancing heat dissipation safety and audio experience, entering smoothing mode.

[0029] In one embodiment, the host computer 120 is further configured to compare the first audio quality, the second audio quality, and the third audio quality, and determine the optimal audio quality from the first audio quality, the second audio quality, and the third audio quality; The optimal control strategy for the cooling fan is determined based on the optimal audio quality. Under the optimal control strategy, the host computer 120 sends a target control signal to the cooling fan to control the cooling fan to enter the target working state. Under the target working state, the quality of the audio data acquired by the audio collector 140 is the optimal audio quality.

[0030] The host computer 120 will also perform quantitative comparisons of the first audio quality under temperature priority state, the second audio quality under audio priority state, and the third audio quality under smooth state, and select the best audio quality with the best sound quality. Based on the best audio quality, the host computer 120 will determine the best control strategy for the cooling fan. Under the best control strategy, the host computer 120 will send a matching target control signal to the cooling fan, so that the fan enters the corresponding target working state, ensuring that the audio data acquired by the audio acquisition unit 140 reaches the best sound quality level in this test.

[0031] It should be noted that in this application, the audio quality of the corresponding audio data is comprehensively evaluated by performing frequency domain analysis, calculating the signal-to-noise ratio, and using international standard algorithms such as PESQ or ViSQOL to objectively score the audio quality of the first, second, and third audio data respectively.

[0032] This enables automated horizontal comparison and selection of the optimal solution among the three control strategies, allowing for the objective and accurate selection of a collaborative control scheme that balances heat dissipation safety and audio performance.

[0033] The collaborative testing system 100 provided in this application embodiment includes: an adjustable temperature chamber 110, a host computer 120, a temperature sensor 130, and an audio acquisition device 140. The host computer 120 is electrically connected to the adjustable temperature chamber 110, the temperature sensor 130, the audio acquisition device 140, and the device under test 200. The device under test 200, the temperature sensor 130, and the audio acquisition device 140 are all placed inside the adjustable temperature chamber 110. The device under test 200 includes: a main control chip and a cooling fan. The temperature sensor 130 is attached to the surface of the main control chip, and the audio acquisition device 140 faces the air outlet of the cooling fan. The temperature sensor 130 is used to acquire the temperature data of the main control chip. The operating temperature of the main control chip is sent to the host computer 120. The operating temperature is positively correlated with the target operating load of the main control chip and the target temperature inside the adjustable temperature chamber 110. The host computer 120 is also used to determine whether the operating temperature meets the preset control conditions. If it does, it sends a control signal to the cooling fan to control the cooling fan to enter the working state. The audio acquisition unit 140 is used to acquire audio data when the device under test 200 plays preset audio while the cooling fan is in the working state, and sends the audio data to the host computer 120. The host computer 120 is used to determine the audio quality of the device under test 200 based on the audio data. This application reproduces the coupled influence of ambient temperature, cooling fan noise and main control chip operating load on audio quality in the actual use scenario of the device under test 200 through integrated collaborative testing, solving the problem that traditional domain testing cannot cover real working conditions, and significantly improving the accuracy of audio quality testing.

[0034] Example 2 In addition, please see Figure 2 This application also provides a collaborative testing method applied to the collaborative testing system 100 described in Embodiment 1. The method includes steps S210 to S240.

[0035] In step S210, the temperature sensor 130 acquires the operating temperature of the main control chip and sends the operating temperature to the host computer 120. The operating temperature is positively correlated with the target operating load of the main control chip and the target temperature inside the adjustable temperature chamber 110.

[0036] In step S220, the host computer 120 determines whether the operating temperature meets the preset control conditions. If it does, it sends a control signal to the cooling fan to control the cooling fan to enter the working state.

[0037] In step S230, the audio acquisition unit 140 acquires the audio data when the cooling fan is in operation and the device under test 200 plays a preset audio, and sends the audio data to the host computer 120.

[0038] In step S240, the host computer 120 determines the audio quality of the device under test 200 based on the audio data. The collaborative testing method provided in this application embodiment is applied to the collaborative testing system 100 described in Embodiment 1. To avoid repetition, it will not be described again here.

[0039] Example 3 Furthermore, this application provides an electronic device 300, including a memory 303 and a processor 302. The memory 303 stores a computer program, which executes the collaborative testing method provided in embodiment 2 when running on the processor 302.

[0040] For details, please see Figure 3 The electronic device 300 includes a transceiver 301, a bus interface, and a processor 302. The processor 302 is used to acquire the operating temperature of the main control chip from the temperature sensor 130 and send the operating temperature to the host computer 120. The operating temperature is positively correlated with the target operating load of the main control chip and the target temperature inside the adjustable temperature chamber 110. The host computer 120 determines whether the operating temperature meets preset control conditions. If it does, it sends a control signal to the cooling fan to control the cooling fan to enter the working state. The audio acquisition unit 140 acquires the audio data when the device under test 200 plays preset audio while the cooling fan is in the working state and sends the audio data to the host computer 120. The host computer 120 determines the audio quality of the device under test 200 based on the audio data. In this embodiment of the application, the electronic device 300 further includes a memory 303. Figure 3In this context, the bus architecture can include any number of interconnected buses and bridges, specifically linking various circuits of one or more processors 302 (represented by processor 302) and various circuits of memory 303 (represented by memory 303). The bus architecture can also link various other circuits such as peripheral devices, voltage regulators, and power management circuits, which are well known in the art and therefore will not be described further herein. The bus interface provides an interface. The transceiver 301 can be multiple elements, including transmitters and receivers, providing a unit for communicating with various other devices over a transmission medium. The processor 302 is responsible for managing the bus architecture and general processing, and the memory 303 can store data used by the processor 302 during operation.

[0041] The electronic device 300 provided in this application embodiment can execute the collaborative testing method provided in the above-described method embodiment 2. To avoid repetition, it will not be described again here.

[0042] Example 4 Furthermore, embodiments of this application provide a computer-readable storage medium storing a computer program that, when executed by a processor, implements the collaborative testing method provided in Embodiment 2.

[0043] In this embodiment, the computer-readable storage medium may be a read-only memory (ROM), a random access memory (RAM), a magnetic disk, or an optical disk, etc.

[0044] The computer-readable storage medium provided in this embodiment can implement the collaborative testing method provided in Embodiment 2. To avoid repetition, it will not be described again here.

[0045] In all examples shown and described herein, any specific values ​​should be interpreted as merely exemplary and not as limitations; therefore, other examples of exemplary embodiments may have different values.

[0046] It should be noted that similar labels and letters in the following figures indicate similar items. Therefore, once an item is defined in one figure, it does not need to be further defined and explained in subsequent figures.

[0047] The embodiments described above are merely illustrative of several implementation methods of this application, and while the descriptions are specific and detailed, they should not be construed as limiting the scope of this application. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of this application, and these modifications and improvements all fall within the protection scope of this application.

Claims

1. A collaborative testing system, characterized in that, The system includes: an adjustable temperature chamber, a host computer, a temperature sensor, and an audio acquisition device. The host computer is electrically connected to the adjustable temperature chamber, the temperature sensor, the audio acquisition device, and the device under test. The device under test, the temperature sensor, and the audio acquisition device are all placed inside the adjustable temperature chamber. The device under test includes a main control chip and a cooling fan. The temperature sensor is attached to the surface of the main control chip, and the audio acquisition device faces the air outlet of the cooling fan. The temperature sensor is used to acquire the operating temperature of the main control chip and send the operating temperature to the host computer. The operating temperature is positively correlated with the target operating load of the main control chip and the target temperature inside the adjustable temperature chamber. The host computer is also used to determine whether the operating temperature meets the preset control conditions. If it does, it sends a control signal to the cooling fan to control the cooling fan to enter the working state. The audio acquisition device is used to acquire audio data when the device under test plays a preset audio while the cooling fan is in operation, and to send the audio data to the host computer. The host computer is used to determine the audio quality of the device under test based on the audio data.

2. The collaborative testing system according to claim 1, characterized in that, The control signals include: a temperature-priority control signal, an audio-priority control signal, or a smoothing control signal; the operating states include: a temperature-priority state, an audio-priority state, or a smoothing state; sending control signals to the cooling fan to control the cooling fan to enter the operating state includes: Send the temperature priority control signal to the cooling fan to control the cooling fan to enter the temperature priority state; The audio data includes: first audio data; the step of acquiring audio data when the cooling fan is in operation and the device under test plays a preset audio, and sending the audio data to the host computer, includes: The system acquires first audio data when the device under test plays a preset audio while the cooling fan is in temperature-priority mode, and sends the first audio data to the host computer. Determining the audio quality of the device under test based on the audio data includes: The first audio quality of the device under test is determined based on the first audio data.

3. The collaborative testing system according to claim 2, characterized in that, Sending a control signal to the cooling fan to control the cooling fan to enter the working state includes: Send the audio priority control signal to the cooling fan to control the cooling fan to enter the audio priority state; The audio data includes: second audio data, wherein acquiring the audio data when the cooling fan is in operation and the device under test plays a preset audio, and sending the audio data to the host computer includes: The system acquires second audio data when the device under test plays a preset audio in the audio priority state, and sends the second audio data to the host computer. Determining the audio quality of the device under test based on the audio data includes: The second audio quality of the device under test is determined based on the second audio data.

4. The collaborative testing system according to claim 3, characterized in that, Sending a control signal to the cooling fan to control the cooling fan to enter the working state includes: Send the smoothing control signal to the cooling fan to control the cooling fan to enter the smoothing state; The audio data includes: third audio data, wherein acquiring the audio data when the cooling fan is in the target operating state and the device under test plays a preset audio, and sending the audio data to the host computer includes: Acquire third audio data when the device under test plays a preset audio in the smooth state of the cooling fan, and send the third audio data to the host computer. Determining the audio quality of the device under test based on the audio data includes: The third audio quality of the device under test is determined based on the third audio data.

5. The collaborative testing system according to claim 4, characterized in that, The host computer is also used to compare the first audio quality, the second audio quality, and the third audio quality, and to determine the best audio quality from the first audio quality, the second audio quality, and the third audio quality; The optimal control strategy for the cooling fan is determined based on the optimal audio quality. Under the optimal control strategy, the host computer sends a target control signal to the cooling fan to control the cooling fan to enter the target working state. Under the target working state, the quality of the audio data acquired by the audio collector is the optimal audio quality.

6. The collaborative testing system according to any one of claims 1-5, characterized in that, The determination of whether the operating temperature meets the preset control conditions includes: Determine whether the operating temperature is greater than a preset temperature threshold. If it is, determine that the operating temperature meets the preset control conditions.

7. The collaborative testing system according to claim 6, characterized in that, Before obtaining the operating temperature of the main control chip, the host computer is also used to send a preset operating script to the main control chip to adjust the operating load of the main control chip to the target operating load; A temperature control signal is sent to the adjustable temperature chamber to control the temperature inside the adjustable temperature chamber to be adjusted to the target temperature.

8. A collaborative testing method, characterized in that, The method, applied to the collaborative testing system of any one of claims 1-7, comprises: The temperature sensor acquires the operating temperature of the main control chip and sends the operating temperature to the host computer. The operating temperature is positively correlated with the target operating load of the main control chip and the target temperature inside the adjustable temperature chamber. The host computer determines whether the operating temperature meets the preset control conditions. If it does, it sends a control signal to the cooling fan to control the cooling fan to enter the working state. The audio acquisition device acquires audio data when the device under test plays a preset audio while the cooling fan is in operation, and sends the audio data to the host computer. The host computer determines the audio quality of the device under test based on the audio data.

9. An electronic device, characterized in that, It includes a memory and a processor, the memory storing a computer program that, when run on the processor, executes the collaborative testing method of claim 8.

10. A computer-readable storage medium, characterized in that, The computer-readable storage medium stores a computer program that, when executed by a processor, implements the collaborative testing method of claim 8.

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