JP5795744B2 - Measuring apparatus and measuring method - Google Patents

Description

  The present invention relates to a measuring apparatus and a measuring method for measuring electrical characteristics of an electronic device.

  Generally, an aging time of several tens of minutes or more is required to ensure a predetermined measurement accuracy after the measurement apparatus is turned on. In a measuring apparatus in which the aging time is defined in advance, it is necessary to measure the elapsed time from the power-on time and monitor for a long time whether or not the elapsed time has reached the specified aging time. Therefore, the user of the measuring device is required to shorten the aging time.

  For example, a spectrum analyzer described in Patent Document 1 has been proposed as a technique focusing on shortening the aging time.

  The thing of patent document 1 is equipped with the temperature sensor which detects the temperature in an apparatus, and the comparator which compares the temperature value at the time of last calibration with the temperature value which the temperature sensor detected, and the comparator compared When the temperature difference exceeds a predetermined temperature difference, the correction value is extracted from the temperature correction table value and is given to the arithmetic processing unit to be corrected to a predetermined measurement accuracy.

  Patent Document 1 describes that the calibration time is instantaneously completed in order to read out the temperature correction table value stored in advance and store the correction value for each temperature and execute the calibration. Patent Document 1 also states that even if the warm-up time (aging time) after power-on is shortened and the measurement is started, the aging time can be shortened because the measurement accuracy can be prevented from being lowered by executing automatic calibration. Has been.

Japanese Patent Laid-Open No. 7-229938

  However, in the aging period from the time when the device is turned on until the time when the temperature inside the device becomes constant, there is a variation in the time required for each location in the device to reach the final stable temperature, and the temperature at just one location or multiple locations. It is difficult to derive a correct correction value from the measurement result. For this reason, even if a certain degree of measurement accuracy can be achieved, a measurement accuracy equivalent to that when the internal temperature becomes constant cannot be realized. For these reasons, the measurement accuracy from the time when the device is turned on until the temperature inside the device becomes constant is generally inferior to the measurement accuracy at the time of completion of aging, and the aging time is shortened. It ’s hard to say.

  The present invention has been made in view of the circumstances as described above, and an object of the present invention is to provide a measuring apparatus and a measuring method capable of reducing the aging time as compared with the conventional one.

The measuring device according to claim 1 of the present invention is a measuring device ( 100 ) for measuring the electrical characteristics of the electronic device (1) to be measured, and an external temperature detecting means for detecting the external temperature of the measuring device. (111), an internal temperature detecting means (52) for detecting the internal temperature of the measuring device, a cooling fan ( 12 ) for cooling the inside of the measuring device, and a cooling fan rotation control for controlling the rotation of the cooling fan Means (113) and the temperature of the heat generating device arranged in the casing of the measuring device for a predetermined use in an aging period from when the measuring device is turned on until the internal temperature reaches a predetermined target temperature. Measurement of the electrical characteristics and the minimum rotation speed table (54) in which the relationship between the minimum rotation speed of the cooling fan and the external temperature at which the air volume not exceeding the upper limit temperature is obtained is determined. A main body (50, 60, 70) having a modularized function and formed with a plurality of detachable measurement modules (50, 60, 70) and a plurality of slot parts (10, 20, 30, 40) to which each of the measurement modules is attached / detached. 110), and the cooling fan rotation control means, at the external temperature detected by the external temperature detection means, on the condition that the internal temperature is lower than the target temperature when the power is turned on, Based on the external temperature and the minimum rotation speed table, the cooling fan is driven at the minimum rotation speed during the aging period, and the internal temperature is higher than the target temperature when the power is turned on. state, and are not to drive the cooling fan at the maximum rotational speed to the aging period, the internal temperature detecting means is provided in the measurement module, the Part temperature detecting means is provided in the main body portion, wherein each measurement module has a structure in which a convergence temperature of the internal temperature converges over time to the target temperature.

With this configuration, the measuring apparatus according to claim 1 of the present invention drives the cooling fan at a low speed when the internal temperature is lower than the target temperature when the power is turned on, and therefore shortens the aging time compared to the conventional one. be able to.
Further, according to this configuration, the measurement apparatus according to claim 1 of the present invention has a low speed when the internal temperature is lower than the target temperature at the time of power-on for each measurement module, even when a plurality of measurement modules are provided. Since the cooling fan is driven at the rotational speed, the aging time can be shortened as compared with the conventional one.
In addition, with this configuration, the measurement apparatus according to claim 1 of the present invention can more accurately realize temperature control in the measurement module by not letting the air flowing through the measurement module through the duct portion. Moreover, the measuring apparatus which concerns on Claim 1 of this invention can reduce the influence of the radiant heat from an adjacent measuring module by a module cover.

  The measuring apparatus according to claim 2 of the present invention has a configuration further comprising notifying means (131) for notifying that the aging period has ended.

  With this configuration, the measuring apparatus according to claim 2 of the present invention can notify the measurer that the aging period has ended.

The measuring device according to claim 3 of the present invention is a measuring device (100) for measuring the electrical characteristics of the electronic device (1) to be measured, and an external temperature detecting means for detecting the external temperature of the measuring device. (111), an internal temperature detecting means (52) for detecting the internal temperature of the measuring device, a cooling fan (12) for cooling the inside of the measuring device, and a cooling fan rotation control for controlling the rotation of the cooling fan Means (113) and the temperature of the heat generating device arranged in the casing of the measuring device for a predetermined use in an aging period from when the measuring device is turned on until the internal temperature reaches a predetermined target temperature. A minimum rotational speed table (54) in which the relationship between the minimum rotational speed of the cooling fan and the external temperature at which an air flow that does not exceed the upper limit temperature is obtained, and the electrical characteristic measuring instrument Is a modularized main body (110) in which a plurality of detachable measurement modules (50, 60, 70) and a plurality of slot portions (10, 20, 30, 40) to which each of the measurement modules is attached and detached are formed. The cooling fan rotation control means includes the internal temperature, the external temperature detected by the external temperature detection means on the condition that the internal temperature is lower than the target temperature when the power is turned on. Based on the external temperature and the minimum rotational speed table, the cooling fan is driven at the minimum rotational speed during the aging period, and the internal temperature is higher than the target temperature when the power is turned on. The cooling fan is driven at the maximum number of rotations during the aging period, and the internal temperature detection means is provided in the measurement module, The temperature detecting means is provided in the main body, and each of the measurement modules has a cylindrical module cover extending from the front panel (116a) of the main body toward the rear panel (116b) along the slot. (57), the main body portion includes a cylindrical duct portion (13) connecting the end portion (57e) on the rear panel side of the module cover to the rear panel, and the cooling fan includes: The module covers of the respective measurement modules are separated from each other when the measurement modules are installed in the slot portions adjacent to each other .

The measuring device according to claim 4 of the present invention is a measuring device (100) for measuring the electrical characteristics of the electronic device (1) to be measured, and an external temperature detecting means for detecting the external temperature of the measuring device. (111), an internal temperature detecting means (52) for detecting the internal temperature of the measuring device, a cooling fan (12) for cooling the inside of the measuring device, and a cooling fan rotation control for controlling the rotation of the cooling fan Means (113) and the temperature of the heat generating device arranged in the casing of the measuring device for a predetermined use in an aging period from when the measuring device is turned on until the internal temperature reaches a predetermined target temperature. A minimum rotational speed table (54) in which the relationship between the minimum rotational speed of the cooling fan and the external temperature at which an air flow that does not exceed the upper limit temperature is obtained, and the electrical characteristic measuring instrument Is a modularized main body (110) in which a plurality of detachable measurement modules (50, 60, 70) and a plurality of slot portions (10, 20, 30, 40) to which each of the measurement modules is attached and detached are formed. ) And an informing means (131) for informing that the aging period has ended, wherein the cooling fan rotation control means has the internal temperature when the power is turned on at the external temperature detected by the external temperature detecting means. The cooling fan is driven at the minimum rotational speed during the aging period based on the internal temperature, the external temperature, and the minimum rotational speed table on the condition that is lower than the target temperature, and the power source The cooling fan is driven at the maximum number of revolutions during the aging period on condition that the internal temperature is higher than the target temperature at the time of charging. Said internal temperature detecting means, wherein provided in the measuring module, the external temperature detecting means, provided in the main body portion, wherein each measurement module along said respective slot portions, the front panel of the main body portion ( 116a) includes a cylindrical module cover (57) extending from the rear panel (116b) toward the rear panel (116b), and the main body extends between the rear panel end (57e) of the module cover and the rear panel. A cylindrical duct portion (13) to be connected is provided, and the cooling fan is provided on a rear panel side in the duct portion, and the measurement modules are mounted when the measurement modules are mounted in adjacent slot portions. The module covers are separated from each other.

  With this configuration, the measurement apparatus according to claim 4 of the present invention can more accurately realize temperature control in the measurement module by not letting the air flowing through the measurement module through the duct portion. Moreover, the measuring apparatus which concerns on Claim 4 of this invention can reduce the influence of the radiant heat from an adjacent measuring module by a module cover.

In the measuring apparatus according to claim 5 of the present invention, the main body is a table provided in the measurement module, and the table value of a target temperature table in which a relationship between the external temperature and the internal temperature is determined in advance is the slot. The main body side target temperature table (119a) stored for each part and the table value of the main body side target temperature table measured on the condition that the measurement module is attached to the slot part. And a target temperature table rewriting means (119b) for rewriting the table value of the target temperature table provided in the module.

A measuring method according to claim 6 of the present invention is a measuring method using the measuring apparatus ( 100 ) according to claim 1, which measures the electrical characteristics of the electronic device (1) to be measured. External temperature detection step (S31) for detecting the external temperature of the device, internal temperature detection step (S32) for detecting the internal temperature of the measuring device, and cooling for controlling the rotation of a cooling fan for cooling the inside of the measuring device A fan rotation control step (S34 to S39), and a heating device disposed in the housing of the measuring device in an aging period from when the measuring device is turned on until the internal temperature reaches a predetermined target temperature. Minimum rotational speed table (5) in which the relationship between the minimum rotational speed of the cooling fan and the external temperature at which the air volume at which the temperature does not exceed the predetermined use upper limit temperature is obtained is determined in advance. ) To obtain the minimum number of revolutions (S36), and at the external temperature detected by the external temperature detection step in the cooling fan rotation control step, the internal temperature is lower than the target temperature when the power is turned on. The cooling fan is driven at the minimum rotational speed during the aging period based on the internal temperature, the external temperature, and the minimum rotational speed table on the condition that the internal temperature is low. The cooling fan is driven at the maximum rotational speed during the aging period on condition that the temperature is higher than the target temperature.

  With this configuration, in the measurement method according to claim 6 of the present invention, when the internal temperature is lower than the target temperature when the power is turned on, the cooling fan is driven at a low speed, so that the aging time is shorter than the conventional one. be able to.

  The present invention can provide a measuring apparatus and a measuring method having an effect that the aging time can be shortened as compared with the conventional one.

It is the plane sectional view and front view showing the composition in a 1st embodiment of the measuring device concerning the present invention. It is side surface sectional drawing which shows the structure in 1st Embodiment of the measuring apparatus which concerns on this invention. It is a functional block diagram which shows the structure in 1st Embodiment of the measuring apparatus which concerns on this invention. It is the figure which showed and graphed an example of the target temperature table in 1st Embodiment of the measuring apparatus which concerns on this invention. It is the figure which showed and graphed an example of the table of the relationship between the minimum rotation speed at the time of aging and external temperature in 1st Embodiment of the measuring apparatus which concerns on this invention. In 1st Embodiment of the measuring apparatus which concerns on this invention, it is a figure which shows typically temperature control in case the internal temperature at the time of power-on is lower than target temperature. In 1st Embodiment of the measuring device which concerns on this invention, it is a figure which shows typically temperature control in case the internal temperature at the time of power-on is higher than target temperature. It is a flowchart which shows the operation | movement which concerns on the temperature control in 1st Embodiment of the measuring apparatus which concerns on this invention. It is a functional block diagram which shows the structure in the modification of 1st Embodiment of the measuring apparatus which concerns on this invention. It is a functional block diagram which shows the structure in 2nd Embodiment of the measuring apparatus which concerns on this invention. It is a flowchart which shows the operation | movement which concerns on the temperature control in 2nd Embodiment of the measuring apparatus which concerns on this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
First, the configuration of the measurement apparatus according to the first embodiment of the present invention will be described. In the first embodiment, an example in which the measurement device according to the present invention is applied to a modular measurement device that measures an output signal of a mobile terminal will be described.

  The modular measuring apparatus 100 in this embodiment has a configuration shown in FIGS. 1A, 1B, and 2 are a cross-sectional plan view, a front view, and a side cross-sectional view, respectively, of the modular measuring apparatus 100. FIG.

  As shown in FIG. 1, the modular measurement apparatus 100 has a main body 110 including a main chassis 116. The modular measuring apparatus 100 constitutes a measuring apparatus according to the present invention.

  The main chassis 116 has a front panel 116a and a rear panel 116b. Further, the main chassis 116 is provided with an external temperature sensor 111 that detects an external temperature (ambient temperature) of the modular measuring apparatus 100 and a power switch 117.

  Inside the main chassis 116, a first slot portion 10, a second slot portion 20, a third slot portion 30, and a fourth slot portion 40 are provided. Measurement modules 50, 60, and 70 are attached to the first slot portion 10, the second slot portion 20, and the third slot portion 30, respectively. The measurement module is not attached to the fourth slot portion 40 and is in an empty state. Normally, the cover 104 is attached to the empty fourth slot portion 40, but FIG. 1B illustrates a state in which the cover 104 is removed in order to explain the inside of the main chassis 116.

  As illustrated, a circuit board 101 on which a CPU, a memory, an IC, and the like are mounted is disposed in the main chassis 116. A connector 41 is provided on the circuit board 101 in the fourth slot portion 40. A printed circuit board of a measurement module attached to the fourth slot portion 40 is inserted into the connector 41.

  The measurement module 50 includes an input terminal 59a that inputs a signal under measurement from a portable terminal (not shown) that is an electronic device to be measured, for example, via a coaxial cable, and a control device that controls measurement processing of the measurement module 50, For example, a communication terminal 59b for communicating with a personal computer (PC) is provided.

  Further, the measurement module 50 includes a cylindrical module cover 57 extending along the first slot portion 10 from the front panel 116a of the main chassis 116 toward the rear panel 116b. The module cover 57 is formed by bending a metal plate, and includes side covers 57a and 57b (see FIG. 1A), an upper cover 57c and a lower cover 57d (see FIG. 2). Have. Two module covers (for example, the side cover 57b of the measurement module 50 and the side cover 60a of the measurement module 60) adjacent to each other of the measurement modules adjacent to each other are separated from each other at a predetermined interval so as to obtain a heat insulating effect by the air layer. Yes.

  Furthermore, the measurement module 50 includes a printed circuit board 58 and an internal temperature sensor 52 inside. As shown in FIG. 2, the printed circuit board 58 includes an insertion portion 58 a that is inserted into the connector 11, and conductive patterns that are in contact with the electrodes of the connector 11 are formed in the insertion portion 58 a.

  In the first slot portion 10 in which the measurement module 50 is mounted, a duct portion 13 that contacts the end portion 57e of the module cover 57 is formed. A cooling fan 12 for the first slot portion 10 is disposed on the rear panel 116 b side in the duct portion 13.

  The cooling fan 12 allows the air in the measurement module 50 to flow in the direction of the arrow shown in FIG. Here, as shown in FIG. 2, the bottom panel of the main chassis 116 is provided with a suction portion 116d formed in a mesh shape, for example. The internal chassis 118 on which the measurement module 50 is mounted and the lower surface cover 57d of the measurement module 50 are also provided with a suction portion (not shown) formed in a mesh shape.

  A power supply unit 120 and a cooling fan 121 of the main body 110 are arranged on the back surface of the circuit board 101.

  Next, based on the functional block diagram shown in FIG. 3, the structure of the modular measuring apparatus 100 in this embodiment is demonstrated.

  As shown in FIG. 3, the modular measuring apparatus 100 includes a first slot portion 10, a second slot portion 20, a third slot portion 30, a fourth slot portion 40, and a main body portion 110. This modular measurement apparatus 100 measures a predetermined characteristic with respect to an output signal of the portable terminal 1 which is an electronic device to be measured, and operates by receiving a control signal from the PC 2.

  The first slot unit 10 includes a measurement module 50, a connector 11, and a cooling fan 12.

  The measurement module 50 includes a measurement unit 51, an internal temperature sensor 52, a target temperature table 53, a minimum rotation number table 54, a module information output unit 55, and a control unit 56.

  The second slot portion 20 and the third slot portion 30 also have the same configuration as the first slot portion 10, respectively. That is, the second slot unit 20 includes a measurement module 60, a connector 21, and a cooling fan 22. The third slot portion 30 includes a measurement module 70, a connector 31, and a cooling fan 32.

  Note that the fourth slot portion 40 also includes the connector 41 and the cooling fan 42, but the measurement module is not attached and is in an empty state. In addition, the configuration of the measurement modules 60 and 70 is the same as that of the measurement module 50, and thus detailed drawings are omitted.

  The main body 110 includes, for example, a CPU, a ROM, a RAM, and the like, and operates according to a control signal from the PC 2. The main body 110 includes an external temperature sensor 111, a module information acquisition unit 112, a cooling fan rotation control unit 113, a drive signal output unit 114, an input / output unit 115, and a notification unit 131.

  Next, a detailed configuration of the measurement module 50 will be described.

  The measurement unit 51 includes a down converter that converts an RF (radio frequency) signal received from the mobile terminal 1 into an IF (intermediate frequency) signal, an AD converter that converts an analog IF signal into a digital signal, and the like. For example, the output signal level of the portable terminal 1 is measured. The measurement unit 51 inputs information such as measurement items and measurement conditions from the PC 2 via the input / output unit 115 and the connector 11, and performs predetermined measurement. The measurement unit 51 outputs measurement result data to the PC 2 via the connector 11 and the input / output unit 115.

  The internal temperature sensor 52 detects the internal temperature of the measurement module 50 and outputs an internal temperature detection signal indicating the internal temperature to the cooling fan rotation control unit 113 via the connector 11. The internal temperature sensor 52 is preferably arranged on the printed circuit board 58 in the measurement module 50 (see FIGS. 1 and 2) and at a relatively large temperature change. The internal temperature sensor 52 constitutes internal temperature detection means according to the present invention.

  The target temperature table 53 is a table in which the relationship between the external temperature and the internal temperature is determined in advance, and includes internal target temperature data for a predetermined external temperature. FIG. 4 is a graph showing an example of the target temperature table 53.

  In FIG. 4, the horizontal axis indicates the external temperature, and the vertical axis indicates the internal temperature. In this example, the target temperature of the internal temperature in the external temperature range of 23 ° C. ± 5 ° C., which is a general measurement external temperature range, is set to 50 ° C. (tolerance is ± 0.25 ° C., for example). This is based on the premise that the modular measuring apparatus 100 is used at room temperature (23 ° C. ± 5 ° C.), and the internal temperature is determined to be 50 ° C. within the room temperature range. Here, since the internal temperature of the measurement module varies depending on the amount of heat generated by the measurement module, for example, a convergence temperature at which the internal temperature converges with the passage of time is obtained in advance as a target temperature for each measurement module. Further, the external temperature range can be arbitrarily determined according to the use environment and application of the measurement module, the blowing capacity of the cooling fan, and the like.

  In the minimum rotation speed table 54, the temperature of the device in the measurement module 50 indicates the use upper limit temperature of the device during the aging period from when the power is turned on until the internal temperature of the measurement module 50 reaches a predetermined target temperature. The relationship between the minimum rotational speed at the time of aging of the cooling fan 12 within the range not exceeding and the external temperature is obtained in advance by, for example, experiments and tabulated.

  For example, the minimum rotation speed table 54 is a table of graph values shown in FIG. FIG. 5 schematically shows the minimum rotational speed during aging, with the horizontal axis representing the external temperature and the vertical axis representing the duty ratio of the PWM signal that determines the rotational speed of the cooling fan 12, which is less than the minimum rotational speed during aging. The region is unusable because it exceeds the upper limit temperature of the device. That is, the minimum rotational speed during aging indicates the minimum rotational speed of the cooling fan 12 so that the temperature of the device in the measurement module 50 does not exceed the upper limit temperature due to self-heating of the device during the aging period. ing.

  Referring to the minimum rotation speed table 54, for example, when the external temperature is 40 ° C., the duty ratio of the PWM signal for obtaining the minimum rotation speed during aging is obtained such that the duty ratio of the PWM signal is 60%. Yes. Note that the minimum rotational speed during aging may be the same as or different from the minimum rotational speed of the cooling fan 12.

  In the measurement module 50, temperature control is performed as shown in FIG. 6 by a cooling fan rotation control unit 113 described later. That is, when the internal temperature at the time of power-on is lower than the target temperature, the cooling fan 12 is driven at the minimum rotational speed at the time of aging according to the external temperature, and the device (for example, CPU) of the maximum heat generation amount in the measurement module 50 The internal temperature reaches the target temperature without the temperature exceeding the upper limit temperature of use of the device. After reaching the target temperature, the cooling fan 12 is driven at a rotational speed that is higher than the minimum rotational speed during aging, so that the temperature of the device changes as shown in the figure and then becomes stable. Here, the cooling fan 12 may be driven at a rotational speed obtained by increasing the minimum rotational speed by a predetermined value during aging.

  In this embodiment, the case where the internal temperature when the power is turned on is lower than the target temperature is described. However, the rotation speed table is prepared in advance also when the internal temperature when the power is turned on is higher than the target temperature. This can be accommodated by the configuration. In this case, as shown in FIG. 7, after the power is turned on, the cooling fan 12 is driven at the maximum rotation speed (duty ratio 100%), and the temperature of the device (for example, CPU) having the maximum heat generation amount in the measurement module 50 is increased. The internal temperature reaches the target temperature without exceeding the use upper limit temperature of the device.

  Returning to FIG. 3, the module information output unit 55 outputs a module information signal indicating that the measurement module 50 is mounted in the first slot unit 10. The module information signal is output to the module information acquisition unit 112 via the connector 11.

  The module information is not limited to the electrical signal as described above. For example, a switch that is mechanically turned on or off is provided in each slot portion, and whether or not the measurement module is inserted into the slot portion is determined. Or it is good also as a structure detected by OFF.

  The control unit 56 includes, for example, a CPU, ROM, RAM, and the like, and controls the operation of the measurement module 50.

  Specifically, the control unit 56 determines the detection signal detected by the internal temperature sensor 52, the signal of the table value stored in the target temperature table 53, and the minimum rotational speed during aging stored in the minimum rotational speed table 54. The operation of outputting the indicated signal and the module information signal from the module information output unit 55 to the main body 110 via the connector 11 is controlled. In addition, the control unit 56 executes the measurement process of the measurement unit 51.

  The cooling fan 12 includes, for example, a variable rotation speed DC motor 12a whose rotation speed is determined by a duty ratio of a pulse signal by PWM (Pulse Width Modulation), a blade 12b rotated by the DC motor 12a, It has.

  Next, a detailed configuration of the main body 110 will be described.

  The external temperature sensor 111 detects the external temperature of the modular measuring apparatus 100 and outputs an external temperature detection signal indicating the external temperature to the cooling fan rotation control unit 113. The external temperature sensor 111 constitutes external temperature detection means according to the present invention.

  The module information acquisition unit 112 acquires module information from the mounted measurement module when the measurement module is mounted in any of the first slot unit 10 to the fourth slot unit 40. For example, the module information acquisition unit 112 acquires module information from the module information output unit 55 via the connector 11 when the measurement module 50 is mounted in the first slot unit 10. As a result, the module information acquisition unit 112 can grasp that the measurement module 50 is mounted in the first slot unit 10. Further, the module information acquisition unit 112 outputs the acquired module information to the cooling fan rotation control unit 113.

  The cooling fan rotation control unit 113 includes an internal temperature detection signal from the internal temperature sensor 52 included in the measurement module 50, a table value signal from the target temperature table 53, and a minimum during aging stored in the minimum rotation speed table 54. A signal indicating the rotation speed and an external temperature detection signal from the external temperature sensor 111 in the main body 110 are input. The cooling fan rotation control unit 113 constitutes a cooling fan rotation control unit according to the present invention.

  In addition, the cooling fan rotation control unit 113 performs cooling based on the internal temperature detection signal from the internal temperature sensor 52, the minimum rotation speed during aging stored in the minimum rotation speed table 54, and the external temperature during the aging period. The rotational speed of the fan 12 is set.

  In addition, the cooling fan rotation control unit 113 sets the internal temperature so that the internal temperature becomes 50 ° C. within the temperature range of 23 ° C. ± 5 ° C. based on the target temperature from the target temperature table 53 after the aging period. The rotational speed of the cooling fan 12 is set while monitoring the internal temperature by the temperature sensor 52.

  The cooling fan rotation control unit 113 also detects the internal temperature from the measurement module 60 installed in the second slot unit 20 and the measurement module 70 installed in the third slot unit 30, as in the measurement module 50. A signal and a target temperature table signal are input, and the rotation speeds of the cooling fans 22 and 32 are set for each measurement module.

  In addition, the cooling fan rotation control unit 113 sets, for example, the minimum number of rotations for the cooling fan 42 in the fourth slot unit 40 in which no measurement module is mounted. A signal including the rotation speed information set by the cooling fan rotation control unit 113 is output to the drive signal output unit 114.

  The drive signal output unit 114 includes a switching element (not shown), turns on and off the switching element, and generates a PWM signal having a predetermined duty ratio. The duty ratio of the PWM signal is determined to be a value that is the number of rotations set for each measurement module by the cooling fan rotation control unit 113. The drive signal output unit 114 outputs each PWM signal to the cooling fans 12, 22, 32 and 42.

  The input / output unit 115 receives signals indicating measurement items and measurement conditions set by the PC 2 and control signals for controlling the operation of the measurement unit 51, and outputs them to the measurement unit 51 via the connector 11. Yes. In addition, the input / output unit 115 receives data of measurement results from the measurement unit 51 and outputs the data to the PC 2. As a result, numerical data, graphs, waveforms, etc. of the measurement results are displayed on the display of the PC 2.

  When all of the measurement modules 50 to 70 have finished aging, the notification unit 131 notifies the measurer, for example, by screen display or audio output. Here, the alerting | reporting part 131 may alert | report sequentially about what completed the aging among the measurement modules 50-70.

  Next, the operation related to the temperature control of the modular measuring apparatus 100 in the present embodiment will be described based on the flowchart shown in FIG. 8 with reference to the functional block diagram of FIG. As shown in FIG. 3, it is assumed that measurement modules 50, 60, and 70 are mounted in the first slot portion 10, the second slot portion 20, and the third slot portion 30, respectively.

  When the power of the modular measuring apparatus 100 is turned on, the control unit 56 of the measurement module 50 mounted in the first slot unit 10 causes the module information acquisition unit 112 to output module information from the module information output unit 55.

  Similarly, each module information is also output to the module information acquisition unit 112 in the measurement module 60 attached to the second slot unit 20 and the measurement module 70 attached to the third slot unit 30.

  As a result, in the module information acquisition unit 112, the first slot unit 10, the second slot unit 20, and the third slot unit 30 are not equipped with measurement modules, and the fourth slot unit 40 is not equipped with a measurement module. Is detected. That is, the module information acquisition unit 112 acquires module configuration information (step S11).

  The external temperature sensor 111 detects the external temperature of the modular measuring apparatus 100 (step S12), and the cooling fan rotation control unit 113 inputs an external temperature detection signal from the external temperature sensor 111.

  The internal temperature sensor 52 detects the internal temperature Tin in the measurement module 50 (step S13), and the control unit 56 outputs an internal temperature detection signal from the internal temperature sensor 52 to the cooling fan rotation control unit 113.

  The control unit 56 outputs a table value signal of the target temperature table 53 to the cooling fan rotation control unit 113, and the cooling fan rotation control unit 113 acquires the table value of the target temperature table 53 and the target temperature Tc (step S14). ).

  The cooling fan rotation control unit 113 compares the internal temperature Tin with the target temperature Tc (step S15). Here, the cooling fan rotation control unit 113 compares the internal temperature Tin with the target temperature Tc in consideration of a predetermined tolerance ΔT (for example, 1 ° C.).

  In step S15, if the internal temperature Tin> the target temperature Tc + ΔT, the cooling fan rotation control unit 113 outputs a signal including rotation speed information for setting the rotation speed of the cooling fan 12 to the maximum rotation speed. Output to. As a result, the cooling fan 12 rotates at the maximum rotation number (step S16).

  In step S15, if the internal temperature Tin <target temperature Tc−ΔT, the cooling fan rotation control unit 113 acquires the information on the minimum rotation speed during aging stored in the minimum rotation speed table 54, and the cooling fan A signal including rotation speed information for setting the rotation speed of 12 to the minimum rotation speed during aging is output to the drive signal output unit 114. As a result, the cooling fan 12 rotates at the minimum rotation speed during aging (step S17).

  Furthermore, in step S15, when target temperature Tc−ΔT <internal temperature Tin <target temperature Tc + ΔT, the process proceeds to step S18 described later.

  Based on the target temperature table 53, the cooling fan rotation control unit 113 monitors the internal temperature Tin so that the internal temperature Tin of the measurement module 50 becomes the target temperature Tc at the external temperature detected by the external temperature sensor 111. The number of rotations of 12 is feedback controlled.

  Specifically, the cooling fan rotation control unit 113 compares the internal temperature Tin with the target temperature Tc (step S18). The target temperature Tc may include a predetermined tolerance (for example, ± 0.25 ° C.) and be compared with the internal temperature Tin.

  In step S18, when the internal temperature Tin is higher than the target temperature Tc (Tin> Tc), the cooling fan rotation control unit 113 displays rotation speed information obtained by increasing the rotation speed of the cooling fan 12 from the current rotation speed. The included signal is output to the drive signal output unit 114.

  The drive signal output unit 114 outputs a PWM signal having a duty ratio at which the rotation speed of the cooling fan 12 becomes the rotation number set by the cooling fan rotation control unit 113 to the cooling fan 12. As a result, the rotational speed of the cooling fan 12 increases (step S19).

  On the other hand, when the internal temperature Tin is lower than the target temperature Tc in step S18 (Tin <Tc), the cooling fan rotation control unit 113 reduces the rotation speed of the cooling fan 12 from the current rotation speed. A signal including information is output to the drive signal output unit 114. In this case, the cooling fan rotation control unit 113 limits the rotation speed of the cooling fan 12 so that it does not become equal to or lower than the minimum rotation speed during aging shown in the minimum rotation speed table 54.

  The drive signal output unit 114 outputs a PWM signal having a duty ratio at which the rotation speed of the cooling fan 12 becomes the rotation number set by the cooling fan rotation control unit 113 to the cooling fan 12. As a result, the number of rotations of the cooling fan 12 decreases (step S20).

  In step S18, when the internal temperature Tin coincides with the target temperature Tc (Tin = Tc), the notification unit 131 notifies the end of aging through screen display, audio output, etc., and returns to step S12.

  In the above description of the operation relating to the temperature control, the measurement module 50 mounted in the first slot unit 10 has been described. However, the measurement modules 60 and 70 mounted in the second slot unit 20 and the third slot unit 30 are also described. The internal temperature is controlled in the same manner as described above. That is, each process of steps S13 to S20 is executed for each module.

  After the aging period, by performing the processes of steps S12 to S15 and S18 to S20, for example, if the target temperature of the measurement module 50 mounted in the first slot unit 10 is 50 ° C., the cooling fan rotation control unit 113 feeds back the internal temperature of the measurement module 50 to 50 ° C. by increasing or decreasing the number of rotations of the cooling fan 12 while monitoring the internal temperature based on the internal temperature detection signal from the internal temperature sensor 52 of the measurement module 50. Control.

  For example, if the target temperature of the measurement module 60 mounted in the second slot unit 20 is 30 ° C., the cooling fan rotation control unit 113 uses the internal temperature detection signal from the internal temperature sensor of the measurement module 60 to detect the internal temperature. While monitoring the above, feedback control is performed so that the internal temperature of the measurement module 60 becomes 30 ° C. by increasing or decreasing the number of rotations of the cooling fan 22.

  For example, if the target temperature of the measurement module 70 mounted in the third slot 30 is 60 ° C., the cooling fan rotation control unit 113 uses the internal temperature detection signal from the internal temperature sensor of the measurement module 70 to detect the internal temperature. While monitoring the above, feedback control is performed so that the internal temperature of the measurement module 70 becomes 60 ° C. by increasing or decreasing the number of rotations of the cooling fan 32.

  In the fourth slot 40, the cooling fan rotation control unit 113 controls, for example, the cooling fan 42 to be driven at the minimum number of rotations.

  As described above, when the internal temperature is lower than the target temperature when the power is turned on, the modular measurement apparatus 100 according to the present embodiment has a low rotational speed for each measurement module mounted in each slot during the aging period. Since the cooling fan is driven, the aging time can be shortened compared to the conventional one.

  Specifically, the conventional aging time required about 30 minutes, but in the module type measuring apparatus 100 in the present embodiment, the aging time was about 15 minutes, which was about half of the conventional aging time. .

  Further, the modular measuring apparatus 100 in the present embodiment controls the number of rotations of the cooling fan provided in each slot portion after the aging period, thereby setting the internal temperature of each measurement module to a predetermined target temperature. The feedback control is performed so as to match the above.

  With this configuration, the modular measurement apparatus 100 can have a target that each measurement module has, even when there are one or a plurality of measurement modules, and even when the measurement modules are installed adjacent to or separated from each other. At the external temperature determined by the table, the internal temperature of each measurement module can be set to a constant target temperature.

(Modification)
A modification of the above embodiment will be described with reference to FIG.

  A modular measurement apparatus 150 shown in FIG. 9 includes a target temperature table 119a and a table update unit 119b in the main body 110. FIG. 9 shows only the main part of the modular measuring apparatus 150.

  The target temperature table 119a stores a target temperature table provided in a measurement module mounted in the slot portion for each slot portion. This target temperature table 119a constitutes a main body side target temperature table according to the present invention. Note that the target temperature table 119a has a target temperature table having a predetermined initial value before the measurement module is mounted in the slot.

  When the measurement module is mounted in the slot, the table update unit 119b acquires a table value signal from the target temperature table of the measurement module, and updates the target temperature table 119a. For example, as illustrated in FIG. 9, when the measurement module 50 is mounted in the first slot unit 10, the table update unit 119 b acquires a table value signal from the target temperature table 53, and uses the acquired table value signal. The table value of the target temperature table 119a is updated. The table updating unit 119b constitutes a target temperature table rewriting unit according to the present invention.

As described above, modular measuring apparatus 150, the measurement module becomes it is sufficient to prepare the data for goal temperature, the structure of the measurement module can be simplified.

  In the above-described embodiment, the measurement apparatus that measures the characteristics of the mobile terminal is exemplified, but the present invention is not limited to this. Examples of the measurement device that performs measurement related to an RF signal like a portable terminal include a spectrum analyzer, a signal analyzer, an RF signal generator, a network analyzer, an RF signal power meter, and an electric field strength measurement device.

  Further, the present invention can be applied to devices other than RF signal-related measuring devices, and is particularly suitable for measuring characteristics (for example, voltage level) that are likely to fluctuate due to temperature changes, and the same effects as in the embodiment can be obtained.

(Second Embodiment)
First, the structure in 2nd Embodiment of the measuring apparatus which concerns on this invention is demonstrated. In the second embodiment, an example in which the measurement apparatus according to the present invention is applied to a single measurement apparatus that measures an output signal of a mobile terminal will be described. In addition, the same code | symbol is attached | subjected to the thing equivalent to the component in 1st Embodiment, and the description is abbreviate | omitted.

  As shown in FIG. 10, the measuring apparatus 200 in the present embodiment has an external temperature sensor 111, an internal temperature sensor 52, a target temperature table 53, a minimum rotation speed table 54, and a cooling fan rotation control unit 113 as a temperature control system configuration. , A drive signal output unit 114, a notification unit 131, and a cooling fan 201.

  The cooling fan 201 includes, for example, a variable rotation speed DC motor 201a whose rotation speed is determined by a duty ratio of a pulse signal by PWM, and a blade 201b rotated by the DC motor 201a.

  The cooling fan rotation control unit 113 receives an external temperature detection signal indicating the external temperature of the measuring apparatus 200 from the external temperature sensor 111, and an internal temperature detection signal indicating the internal temperature of the measuring apparatus 200 from the internal temperature sensor 52, and the target temperature table 53. The table value signal including the target temperature data is input from the minimum rotation speed table 54 and the signal indicating the minimum rotation speed during aging is input. Based on the external temperature, the internal temperature, the target temperature table 53 and the minimum rotation speed table 54 Thus, the rotational speed of the cooling fan 201 is set.

  The drive signal output unit 114 determines the duty ratio of the PWM signal so that the rotation speed set by the cooling fan rotation control unit 113 is set, and outputs the PWM signal to the cooling fan 201.

  The measurement apparatus 200 includes a measurement unit 51, a display unit 202, an operation unit 203, and a setting unit 204 as the configuration of the measurement system.

  The measurement unit 51 measures, for example, the signal level of the mobile terminal 1 based on the measurement conditions and measurement items (hereinafter referred to as “measurement conditions etc.”) set by the setting unit 204.

  The display unit 202 displays the measurement result of the measurement unit 51 based on the measurement conditions set by the setting unit 204.

  The operation unit 203 is operated by a measurer to make settings related to measurement conditions and the like, and includes, for example, an input device such as a keyboard, a dial, or a mouse, and a control circuit that controls these devices.

  The setting unit 204 outputs setting signals for setting measurement conditions and the like set by the measurer operating the operation unit 203 to the measurement unit 51 and the display unit 202, and sets the measurement conditions and the like.

  Next, operations related to temperature control of the measuring apparatus 200 in the present embodiment will be described based on the flowchart shown in FIG. 11 with reference to the functional block diagram of FIG. 10 as appropriate.

  The external temperature sensor 111 detects the external temperature of the modular measuring apparatus 100 (step S31), and the cooling fan rotation control unit 113 inputs an external temperature detection signal from the external temperature sensor 111.

  The internal temperature sensor 52 detects the internal temperature Tin in the measurement module 50 (step S32), and the control unit 56 outputs an internal temperature detection signal from the internal temperature sensor 52 to the cooling fan rotation control unit 113.

  The control unit 56 outputs a table value signal of the target temperature table 53 to the cooling fan rotation control unit 113, and the cooling fan rotation control unit 113 acquires the table value of the target temperature table 53 and the target temperature Tc (step S33). ).

  The cooling fan rotation control unit 113 compares the internal temperature Tin with the target temperature Tc (step S34). Here, the cooling fan rotation control unit 113 compares the internal temperature Tin with the target temperature Tc in consideration of a predetermined tolerance ΔT (for example, 1 ° C.).

  If the internal temperature Tin> the target temperature Tc + ΔT in step S34, the cooling fan rotation control unit 113 outputs a signal including the rotation speed information for setting the rotation speed of the cooling fan 12 to the maximum rotation speed. Output to. As a result, the cooling fan 12 rotates at the maximum number of rotations (step S35).

  In step S34, when the internal temperature Tin <target temperature Tc−ΔT, the cooling fan rotation control unit 113 acquires information on the minimum rotation speed during aging stored in the minimum rotation speed table 54, and the cooling fan A signal including rotation speed information for setting the rotation speed of 12 to the minimum rotation speed during aging is output to the drive signal output unit 114. As a result, the cooling fan 12 rotates at the minimum rotation speed during aging (step S36).

  Furthermore, in step S34, when the target temperature Tc−ΔT <the internal temperature Tin <the target temperature Tc + ΔT, the process proceeds to step S22 described later.

  Based on the target temperature table 53, the cooling fan rotation control unit 113 monitors the internal temperature Tin so that the internal temperature Tin of the measurement module 50 becomes the target temperature Tc at the external temperature detected by the external temperature sensor 111. The number of rotations 201 is feedback controlled.

  Specifically, the cooling fan rotation control unit 113 compares the internal temperature Tin with the target temperature Tc (step S37). The target temperature Tc may include a predetermined tolerance (for example, ± 0.25 ° C.) and be compared with the internal temperature Tin.

  In step S37, when the internal temperature Tin is higher than the target temperature Tc (Tin> Tc), the cooling fan rotation control unit 113 displays rotation speed information obtained by increasing the rotation speed of the cooling fan 201 from the current rotation speed. The included signal is output to the drive signal output unit 114.

  The drive signal output unit 114 outputs a PWM signal having a duty ratio at which the rotation speed of the cooling fan 201 becomes the rotation number set by the cooling fan rotation control unit 113 to the cooling fan 201. As a result, the rotational speed of the cooling fan 201 increases (step S38).

  On the other hand, when the internal temperature Tin is lower than the target temperature Tc in Step S37 (Tin <Tc), the cooling fan rotation control unit 113 reduces the rotation speed of the cooling fan 201 from the current rotation speed. A signal including information is output to the drive signal output unit 114. In this case, the cooling fan rotation control unit 113 limits the rotation speed of the cooling fan 12 so that it does not become equal to or lower than the minimum rotation speed during aging shown in the minimum rotation speed table 54.

  The drive signal output unit 114 outputs a PWM signal having a duty ratio at which the rotation speed of the cooling fan 201 becomes the rotation number set by the cooling fan rotation control unit 113 to the cooling fan 201. As a result, the rotational speed of the cooling fan 201 is reduced (step S39).

  In step S37, when the internal temperature Tin coincides with the target temperature Tc (Tin = Tc), the notification unit 131 notifies the end of aging through screen display, audio output, and the like, and returns to step S31.

  As described above, when the internal temperature is lower than the target temperature when the power is turned on, the measuring device 200 according to the present embodiment has a cooling fan at a low rotational speed for each measurement module installed in each slot during the aging period. , The aging time can be shortened compared to the conventional one.

  As described above, the measuring apparatus and the measuring method according to the present invention have an effect that the aging time can be shortened compared with the conventional one, and are as a measuring apparatus and a measuring method for measuring the electrical characteristics of an electronic device. Useful.

1 Mobile terminal (electronic equipment)
DESCRIPTION OF SYMBOLS 10 1st slot part 12, 22, 32, 42, 201 Cooling fan 13 Duct part 20 2nd slot part 30 3rd slot part 40 4th slot part 50, 60, 70 Measurement module 52 Internal temperature sensor (Internal temperature detection means )
53 Target temperature table 54 Minimum rotation speed table 55 Module information output unit 57 Module cover 57a, 57b, 60a Side cover 57e Module cover end 100, 150 Modular measuring device (measuring device)
110 Body 111 External temperature sensor (external temperature detection means)
112 Module information acquisition unit 113 Cooling fan rotation control unit (cooling fan rotation control means)
114 Drive signal output unit 116 Main chassis 116a Front panel 116b Rear panel 119a Target temperature table (main body side target temperature table)
119b Table updating unit (target temperature table rewriting means)
131 Notification unit (notification means)
200 Measuring device

Claims (6)

A measuring device ( 100 ) for measuring electrical characteristics of an electronic device (1) to be measured,
An external temperature detecting means (111) for detecting an external temperature of the measuring device;
An internal temperature detecting means (52) for detecting the internal temperature of the measuring device;
A cooling fan ( 12 ) for cooling the inside of the measuring device;
Cooling fan rotation control means (113) for controlling rotation of the cooling fan;
The air volume at which the temperature of the heat generating device arranged in the casing of the measuring device does not exceed a predetermined upper limit temperature during the aging period from when the measuring device is turned on until the internal temperature reaches a predetermined target temperature A minimum rotation speed table (54) in which the relationship between the minimum rotation speed of the cooling fan and the external temperature is obtained in advance,
A plurality of measurement modules (50, 60, 70) in which the measurement function of the electrical characteristics is modularized and detachable;
A main body portion (110) formed with a plurality of slot portions (10, 20, 30, 40) to which each measurement module is attached and detached;
With
The cooling fan rotation control means is configured such that, at the external temperature detected by the external temperature detection means, the internal temperature, the external temperature, and the minimum rotation are provided on condition that the internal temperature is lower than the target temperature when the power is turned on. Based on a number table, the cooling fan is driven at the minimum number of rotations during the aging period, and the maximum number of rotations during the aging period is provided on condition that the internal temperature is higher than the target temperature when the power is turned on. all SANYO for driving the cooling fan by the number,
The internal temperature detection means is provided in the measurement module,
The external temperature detection means is provided in the main body,
Each measuring module uses the convergence temperature at which the internal temperature converges with time as the target temperature .   The measuring apparatus according to claim 1, further comprising notification means (131) for notifying that the aging period has ended. A measuring device (100) for measuring electrical characteristics of an electronic device (1) to be measured,
An external temperature detecting means (111) for detecting an external temperature of the measuring device;
An internal temperature detecting means (52) for detecting the internal temperature of the measuring device;
A cooling fan (12) for cooling the inside of the measuring device;
Cooling fan rotation control means (113) for controlling rotation of the cooling fan;
The air volume at which the temperature of the heat generating device arranged in the casing of the measuring device does not exceed a predetermined upper limit temperature during the aging period from when the measuring device is turned on until the internal temperature reaches a predetermined target temperature A minimum rotation speed table (54) in which the relationship between the minimum rotation speed of the cooling fan and the external temperature is obtained in advance,
A plurality of measurement modules (50, 60, 70) in which the measurement function of the electrical characteristics is modularized and detachable;
A main body portion (110) formed with a plurality of slot portions (10, 20, 30, 40) to which each measurement module is attached and detached;
With
The cooling fan rotation control means is configured such that, at the external temperature detected by the external temperature detection means, the internal temperature, the external temperature, and the minimum rotation are provided on condition that the internal temperature is lower than the target temperature when the power is turned on. Based on a number table, the cooling fan is driven at the minimum number of rotations during the aging period, and the maximum number of rotations during the aging period is provided on condition that the internal temperature is higher than the target temperature when the power is turned on. The cooling fan is driven by a number,
The internal temperature detection means is provided in the measurement module,
The external temperature detection means is provided in the main body,
Each measurement module includes a cylindrical module cover (57) extending from the front panel (116a) to the rear panel (116b) of the main body along the slot.
The body part is
A cylindrical duct portion (13) for connecting the end (57e) on the rear panel side of the module cover to the rear panel;
The cooling fan is provided on the rear panel side in the duct portion,
The measurement apparatus , wherein the module covers of the measurement modules are separated from each other when the measurement modules are mounted in adjacent slot portions . A measuring device (100) for measuring electrical characteristics of an electronic device (1) to be measured,
An external temperature detecting means (111) for detecting an external temperature of the measuring device;
An internal temperature detecting means (52) for detecting the internal temperature of the measuring device;
A cooling fan (12) for cooling the inside of the measuring device;
Cooling fan rotation control means (113) for controlling rotation of the cooling fan;
The air volume at which the temperature of the heat generating device arranged in the casing of the measuring device does not exceed a predetermined upper limit temperature during the aging period from when the measuring device is turned on until the internal temperature reaches a predetermined target temperature A minimum rotation speed table (54) in which the relationship between the minimum rotation speed of the cooling fan and the external temperature is obtained in advance,
A plurality of measurement modules (50, 60, 70) in which the measurement function of the electrical characteristics is modularized and detachable;
A main body portion (110) formed with a plurality of slot portions (10, 20, 30, 40) to which each measurement module is attached and detached;
Informing means (131) for informing that the aging period has ended,
With
The cooling fan rotation control means is configured such that, at the external temperature detected by the external temperature detection means, the internal temperature, the external temperature, and the minimum rotation are provided on condition that the internal temperature is lower than the target temperature when the power is turned on. Based on a number table, the cooling fan is driven at the minimum number of rotations during the aging period, and the maximum number of rotations during the aging period is provided on condition that the internal temperature is higher than the target temperature when the power is turned on. The cooling fan is driven by a number,
The internal temperature detection means is provided in the measurement module,
The external temperature detection means is provided in the main body,
Each measurement module includes a cylindrical module cover (57) extending from the front panel (116a) to the rear panel (116b) of the main body along the slot.
The main body is
A cylindrical duct portion (13) for connecting the end (57e) on the rear panel side of the module cover to the rear panel;
The cooling fan is provided on the rear panel side in the duct portion,
Wherein when mounted in the slot section each measurement module are adjacent to each other, said module cover measurement device you characterized in that spaced apart from each other in the respective measurement module. The main body is
A main body-side target temperature table (119a) that stores a table value of a target temperature table, which is a table provided in the measurement module and for which a relationship between the external temperature and the internal temperature is predetermined, for each slot portion;
Rewriting the target temperature table rewriting the table value of the target temperature table on the main body side to the table value of the target temperature table provided in the measurement module mounted on the slot, provided that the measurement module is mounted on the slot. Means (119b);
The measuring apparatus according to claim 1, 3, or 4. A measuring method using the measuring device ( 100 ) according to claim 1, which measures the electrical characteristics of the electronic device (1) to be measured,
An external temperature detection step (S31) for detecting an external temperature of the measuring device;
An internal temperature detecting step (S32) for detecting the internal temperature of the measuring device;
A cooling fan rotation control step (S34 to S39) for controlling rotation of a cooling fan for cooling the inside of the measuring device;
The air volume at which the temperature of the heat generating device arranged in the casing of the measuring device does not exceed a predetermined upper limit temperature during the aging period from when the measuring device is turned on until the internal temperature reaches a predetermined target temperature Obtaining the minimum number of rotations from the minimum number of rotations table (54) in which the relationship between the minimum number of rotations of the cooling fan and the external temperature obtained in advance is determined (S36);
Including
In the cooling fan rotation control step, the internal temperature, the external temperature, and the minimum rotation of the external temperature detected in the external temperature detection step are set on condition that the internal temperature is lower than the target temperature when the power is turned on. Based on a number table, the cooling fan is driven at the minimum number of rotations during the aging period, and the maximum number of rotations during the aging period is provided on condition that the internal temperature is higher than the target temperature when the power is turned on. A measurement method, characterized in that the cooling fan is driven by a number.

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