KR20120115726A - Method and apparatus for power on/off test - Google Patents

Abstract

PURPOSE: A power on-off test method and a device thereof are provided to output whether a UUT(Unit Under Test) is normally booted or not by turning on or off power for the UUT. CONSTITUTION: When a relay(150) is turned on, the relay supplies power to a UUT(190). When the relay is turned off, the relay blocks the power to the UUT. A micom(140) turns on or off the relay at a specific time. After the power is supplied to the UUT, the micom determines the success of a booting test for the UUT based on a booting message received from the UUT. [Reference numerals] (110) Receiver; (150) Relay; (155) Switch; (160) AC input; (170) AC connector; (180) Monitor; (AA, BB) Power source; (CC) On/Off control

Description

Power ON / OFF test method and apparatus {METHOD AND APPARATUS FOR POWER ON / OFF TEST}

The following embodiments are directed to a method and apparatus for performing a power on / off test for a UUT.

If the device is used for a long time and the power is frequently turned on / off, the device may be damaged and may malfunction.

Therefore, there is a need for a power on / off device that automatically checks a test for power on / off of a device.

The device under test of the power ON / OFF equipment, that is, the unit under test (UUT), may be any kind of electronic product that does not operate on a battery. That is, a device that operates by directly receiving AC power and a device using a direct current (DC) adapter may be a test unit, and a test of the device is performed by opening and closing the power of these devices. do.

Existing power ON / OFF equipment short-circuits the equipment a certain number of times (i.e., after power on / off a certain number of times) and judges only the unit under test. Here, a short circuit means connecting and disconnecting a contact of a power relay. In other words, a short circuit means blocking the inflow of power to the UUT.

Therefore, it is difficult to determine whether the UUT is normally booted with the existing power ON / OFF equipment.

Therefore, there is a need for a power ON / OFF device that can determine whether the UUT is normally booted when the power is ON or OFF.

An embodiment of the present invention may provide an apparatus and a method for outputting whether a UUT is normally booted by performing power on / off of a UUT.

One embodiment of the present invention can provide an apparatus and method for repeatedly performing the power ON / OFF for the UUT.

According to one aspect of the present invention, a power supply to the unit under test (UUT) when it is turned on, and a relay to turn off the power to the UUT when turned off, and MICOM (microprocessor) for turning on or off the relay at a specific time The MICOM is provided with a power on / off device for determining whether a boot test for the UUT is successful or failed based on a boot message received from the UUT after power is supplied to the UUT.

The MICOM may turn the relay on or off at the specific time by applying a control signal to turn on or off the relay at the specific time.

The MICOM may determine whether the boot check for the UUT succeeds or fails depending on whether the boot message includes a string indicating that the boot of the UUT is successful.

The string indicating that the boot was successful may be a specific part of a message output when the UUT successfully boots.

There may be a plurality of UUTs, and the MICOM may determine success or failure of a boot check for each of the plurality of UUTs.

The plurality of UUTs may be heterogeneous devices.

The power on / off device may further include a power strip including a plurality of spheres for distributing power supplied from the relay, wherein each of the plurality of UUTs supplies power through one of the plurality of spheres. Can be supplied.

The power on / off device may further include a receiver for receiving a message output from the UUT and a UART FIFO for storing a message received by the receiver in a first in first out (FIFO), the MICOM May read a message from the FIFO.

The power on / off device may further include an electrically programmable logic device (EPLD) for generating a control signal for the MICOM to read the message in the UART FIFO.

The MICOM may output the result of the determination to the console.

The power on / off device is an AC connector for supplying power to the UUT

It may further include, and the relay may switch the power supply to the AC connector to ON / OFF.

The MICOM may repeat ON and OFF of the relay a predetermined number of times at any time period.

The MICOM may determine whether the UUT has normally booted every time the relay is turned on and off.

The MICOM may store as a log file whether a boot failure occurs during execution of any part of the program of the UUT.

The MICOM may operate according to a setting value, wherein the setting value is a delay time until the UUT turned off, a delay time until the UUT receives the message from the UUT after the UUT is turned on, and the May include one or more of the times for monitoring the predefined string output from the UUT

The setting value may be input to the MICOM through a console.

According to another aspect of the present invention, the operation of turning off the power of the UUT, the operation of turning on the power of the UUT, the operation of receiving a message from the UUT and the operation of determining whether the normal booting of the UUT based on the message Including a power on / off test method is provided.

The power on / off test method may further include an operation of waiting for a predetermined time before turning on the power of the UUT again and of waiting for a predetermined time before receiving the message from the UUT.

The power on / off test method may further include determining whether a predetermined time elapsed to receive the message from the UUT has elapsed.

The normal booting may be determined according to whether there is a string indicating that the booting of the UUT is successful.

The power on / off test method is configured to output a result of the determination to a console.

As shown in FIG.

The power on / off test method may further include an operation of checking whether the number of times power on / off is tested is equal to a predefined value.

An apparatus and method for outputting whether a UUT is normally booted by performing power ON / OFF for a UUT is provided.

An apparatus and method are provided for repeatedly performing power ON / OFF for a UUT.

1 is a structural diagram of a power on / off device 100 according to an embodiment of the present invention.
2 is a view showing a connection relationship between the power ON / OFF device 100 and the UUT 190 according to an embodiment of the present invention.
3 illustrates a setting screen of the console 240 according to an embodiment of the present invention.
4 illustrates a screen for inputting setting values through a console according to an embodiment of the present invention.
5 illustrates a screen showing a booting result of the UUT 190 according to an embodiment of the present invention.
6 is a flowchart illustrating a power on / off test method according to an embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to or limited by the embodiments. Like reference symbols in the drawings denote like elements.

1 is a structural diagram of a power on / off device 100 according to an embodiment of the present invention.

The power ONF / OFF device 100 includes a receiver 110, a universal asynchronous receiver transmitter first in first out (UART FIFO) 120, an electrically programmable logic device (EPLD); Logic device 130, MICOM (microprocessor) 140, relay 150, alternating current (AC) input 160, AC connector 170, and A monitor 180.

Receiver 110 receives a boot message from UUT 190 via a serial cable. The test boards of the receiver 110 and the UUT 190 may communicate with each other via the UART.

The serial cable may be a 9-pin male-male cable.

The receiver 120 may be connected to a test board of the UUT 190 or a console of the test board.

The receiver 110 receives a message (eg, string or text information) output from the UUT 190.

In general, receiver 110 operates from a single + 3.3V power supply.

The receiver 110 may have a characteristic of a maximum ICX 10 μA in the shutdown mode. In addition, the receiver 110 may have a low power requirement of up to ICC 20 mA.

The UART FIFO 120 stores the message received from the receiver 110 in the FIFO. The FIFO can be 64 bytes. The receiver 110 and the UART FIFO 120 may communicate with each other via the UART. UART may be based on RS232 (Recommended Standard 232) communication (ie, 16550 protocol).

UART FIFO 120 may support a 50-MHz input clock (3 Mbps) for 5-V (Volt) operation.

UART FIFO 120 may support a 35-MHz input clock (2 Mbps) for 3.3-V (Volt) operation.

UART FIFO 120 may support a 3-3-V or 5-V supply.

UART FIFO 120 may have an operating characteristic from -40 ℃ to 85 ℃.

UART FIFO 120 may be a 64-byte transmit FIFO.

The EPLD 130 generates a control signal necessary for the MICOM 140 to read the message data in the UART FIFO 120.

The EPLD 130 may use a multi voltage of one or more of 2.5V, 3.3V, and 5V.

The EPLD 130 may support an In System Programming (ISP) function.

The EPLD 130 may support a Joint Test Action Group (JTAG) (IEEE 1149.1) boundary scan test function.

The MICOM 140 turns on / off the relay 150 according to a specific time input through the UI (User Interface).

The MICOM 140 may turn the relay 150 on or off at a specific time by applying a control signal for turning the relay 150 on or off at a specific time.

When the relay 150 is turned on, the relay 150 supplies power to the UUT 190. When the relay 150 is turned off, the relay 150 cuts off power to the UUT 190.

The MICOM 140 determines that the boot check for the UUT 190 is PASS (success) or FAIL (failure) based on the boot message received from the UUT 190 after power is supplied to the UUT 190. .

The MICOM 140 may confirm that a boot message is a specific string indicating that the boot of the UUT 190 succeeded (that is, a string indicating that the boot of the UUT 190 succeeded or that the UUT 190 has normally booted. Or a boot message), it may be determined that the result of the boot check for the UUT 190 is success or failure.

The specific string may be a specific part of a message that is output when the UUT 190 successfully boots. For example, the specific string may be a string indicating success such as "PASS" or "GOOD".

Alternatively, after the power is supplied to the UUT 190, the MICOM 140 may receive a boot message from the UUT 190 to determine the success or failure of the boot test for the UUT 190. In this case, when the booting of the UUT 190 succeeds, the booting message may be a message including a specific message such as “PASS” or “GOOD”.

The received message from UUT 190 may be message data in UART FIFO 120.

The MICOM 140 may transmit the result of the determination to the monitor 180 (or the console 240 to be described later). The monitor 180 may output a result of the determination. MICOM 140 and monitor 180 may communicate with each other using a UART. The UART may be a full duplex UART serial channel.

MICOM 140 may be an 8K byte ISP flash memory.

MICOM 140 may have an operating range from 4.0V to 5.5V.

The MICOM 140 may support a low-power idle mode and a power-down mode.

MICOM 140 may have 32 programmable I / O lines.

The MICOM 140 may support fully static operation from 0 Hz to 33 Mhz.

The relay 150 supplies or cuts off power to the UUT 190. That is, the relay 150 may short-circuit the power applied to the UUT 190. The relay 150 is controlled by the control signal of the MICOM 140.

The relay 150 may be a switching power supply.

The relay 150 may have a large capacity within a small size. For example, the relay 150 may have a characteristic of 10A 250V AC.

The switch 155 indicates that the relay 150 can switch the power supply to the AC connector 170 ON / OFF.

AC input 160 is an external power input. Power required to drive the power ON / OFF device 100 and power supplied to the UUT 190 are applied to the AC input 160.

AC connector 170 supplies power to UUT 190. The AC connector 170 may supply power to the plurality of UUTs 190 through an extension cable.

The UUT 190 is a device to be inspected by the power ON / OFF device 100.

When AC power is supplied to the power ON / OFF device 100 through the AC input 160, the power ON / OFF device 100 operates by the AC power. The power on / off device 100 provides the AC power to the power of the UUTs 190 by bypassing the AC power.

The power ON / OFF device 100 may check whether the UUT 190 is abnormal by blocking (ie, turning off) the AC power being bypassed and connecting (ie, turning on).

The power ON / OFF device 100 may apply a large number of power ON / OFF to the UUT 190, and after a large number of power ON / OFF tests, may determine whether the UUT 190 performs normal operation. By this inspection, reliability as a product of the UUT 190 can be secured.

Here, a large number of tests may mean that the UUT 190 may be connected to the power on / off device 100 to repeat the power on / off test up to tens of thousands of times for the UUT 190. In addition, a large number of tests may mean that a large number of UUTs 190 may be connected to the power on / off device 100 to repeat the power on / off test for a large number of UUTs 190. have. That is, a large number of tests may mean a large number of tests for one device (ie, the UUT 190), and may mean a test for a large number of devices (ie, the UUTs 190). can do.

That is, the power ON / OFF device 100 may determine whether the UUT 190 (that is, the board of the UUT 190) boots normally without a problem after a large number of power ON / OFF. .

Normal booting means that the UUT 190 (that is, the board of the UUT 190) boots without any problem and enters the stage where the UUT 190 can perform normal device operation.

In general, the device displays the execution process of the program to the outside through the console port of the main processor during the product development stage. In addition, when all settings required for booting of the device are completed and the check for the device is completed, no further message is output from the device.

At this time, the device outputs a predetermined predefined boot completion string (or text information) (eg, "BOOTING OK", "PASS" or "GOOD") after the last message output related to booting is completed. If so (ie, the device is programmed to output a boot complete string), then the power on / off device 100 (specifically, MICOM 140) has received the boot complete string from the UUT 190. By checking whether the UUT 190 can be normally booted or not.

The boot completion string may be a specific string indicating that the aforementioned boot is successful. Alternatively, the boot completion string may include a specific string indicating that the aforementioned boot is successful.

In addition to the boot completion string, text information or special signal characters indicating boot success, pass, good, etc. may be promised between the UUT 190 and the power ON / OFF device 100 in advance.

The console of the UUT 190 and the console of the power ON / OFF device 100 may be interconnected, and the power ON / OFF device 100 may detect such text information or a special signal character among information transmitted from the UUT 190. By detecting, it is possible to determine whether the UUT 190 performed normal operation.

After power is applied to the UUT 190, the time until the UUT 190 outputs a message containing a specific character string may be regarded as almost constant. Thus, before and after the time at which the message is expected to be output, the ELPD 130 may continue to read the data accumulated in the UART FIO 120 (ie, the message transmitted from the UUT 190). If the boot completion string is among the data read by the ELDP 130, the ELPD 130 may inform the MICOM 140 that the check for the UUT 190 was successful.

The MICOM 140 outputs that the UUT 190 passes the test through the monitor 180 (or an external console).

The power supply ON / OFF apparatus 100 may repeat the power supply ON / OFF a predetermined number of times at any time period. That is, the MICOM 140 may repeat the ON and OFF of the relay 150 by a predetermined number of time periods.

In addition, the power ON / OFF device 100 (that is, MICOM 140) determines whether the UUT 190 has normally booted at every power ON / OFF (that is, ON / OFF of the relay 150). can do.

The power on / off device 100 may know when and on which test a boot failure that may occur during a test occurs during a predetermined number of times of power on / off. The ON / OFF device 100 (that is, the MICOM 140) may store as a log file whether a boot failure occurs during execution of a program of the UUT 190. These log files can provide debugging convenience for the operator.

Since the UUT 190 and the power ON / OFF device 100 communicate using the UART, the results of the test (i.e. messages related to booting output from the UUT 190) are transmitted via the UART interface. Is sent to 100.

Thus, the operation of the UUT 190 can be quickly tested by using a device (i.e., the power ON / OFF device 100), compared to the person measuring the test results while operating the UUT 190. Effective testing can be performed while reducing the number of people and time.

2 is a view showing a connection relationship between the power ON / OFF device 100 and the UUT 190 according to an embodiment of the present invention.

The power strip 210 is connected to the AC connector 170 of the power on / off device 100.

Through the power strip 210, the power turned on / off by the power on / off device 100 is supplied to the plurality of UUTs 190. That is, the multi-tap 210 distributes the power supplied from the relay 150 or the AC connector 170 through the plurality of spheres.

The power cable 220 of each of the plurality of UUTs 190 is plug-in to a sphere of the power strip 210. That is, each of the plurality of UUTs 190 is supplied with power through one of the plurality of spheres included in the multi-tap 201.

The number of UUTs 190 that may be connected to the power ON / OFF device 100 through the power strip 210 may be flexibly adjusted. Thus, the multi-tap 210 can be used for miniaturization of the power ON / OFF device 100 and can be used for scalability of the number of UUTs 190 that can be tested at the same time.

In FIG. 2, four UUTs 190 are connected to a power on / off device 100.

By the power on / off device 100, the plurality of UUTs 190 may be powered on / off at the same time. Thus, the plurality of UUTs 190 may be examined at the same time. That is, the power ON / OFF device 100 (or MICOM 140) may determine the success or failure of the boot test for each of the plurality of UUTs 190.

The plurality of UUTs 190 may be homogeneous devices or heterogeneous devices.

Each of the plurality of UUTs 190 transmits a message to a power ON / OFF device through a signal line 230 such as a UART. That is, the plurality of signal lines 230 are connected to the receiver 110. Optionally, the power ON / OFF device 100 may provide the same receiver 110 to all of the plurality of signal lines (ie, the receiver 110 and the UART FIFO 120 are shared by the plurality of UUTs 190). A separate receiver 110 and the same UART FIFO 120 for each of the plurality of signal lines (i.e., the UART FIFO 120 is shared to the plurality of UUTs 190) or a plurality of A separate receiver 110 and a separate UART FIFO 120 may be provided for each of the signal lines.

The console 240 receives a message output from the MICOM 150.

Console 240 may be a personal computer (PC).

The console 240 and the power ON / OFF device 100 may be connected through a USB serial cable.

The console 240 may provide an interface required for the operation of the power ON / OFF device 100.

The console 240 may display internal operations of the power ON / OFF device 100. That is, the console 240 may output information about which of the plurality of UUTs 190 has failed to boot in a few times of operations.

3 illustrates a setting screen of the console 240 according to an embodiment of the present invention.

The console 240 may refer to a PC running a serial communication program. That is, the setting screen of the console 240 may be a screen of a serial communication program running on a PC.

The port to be used in the serial communication program needs to be selected. (For example, "USB Serial Port" should be selected in the "Serial Port" item.) The port to be used can be checked in the port (com & lpt) item of the device manager of the control panel of the PC.

Items for the initial setup of the serial communication program may be stored in a specific file (eg, onoff.ini).

Through the serial communication program, a communication scheme between the console 240 and the power ON / OFF device 100 may be set. For example, the serial communication program may select a baud rate between the console 240 and the power on / off device 100. That is, the baud rate may be the UART baud rate of the UUT 190.

In Fig. 3, "115200" was selected as the baud rate.

In addition, a setting value for the operation of the power ON / OFF device 100 may be input and set through a serial communication program. That is, the setting value may be input to the MICOM 140 through the console 240.

The MICOM 140 may operate according to a setting value.

The setting value may include the setting values of 1) to 4) below.

1) OFF-ON delay: This is the delay time until the turned off UUT 190 is turned on. That is, the time when the UUT 190 is powered off.

2) ON-READ Delay: This is the delay time after the UUT 190 is turned on, until the measurement for the UUT 190 starts (i.e., receiving a message from the UUT 190). That is, the time taken for the UUT 190 to boot normally.

3) READ-OFF delay: After the ON-READ delay time, the power ON-OFF device 100 monitors the predefined character string output from the UUT 190.

4) COMP.String: A string representing the boot message. COMP.String may be a predefined string or a string of parts to be measured.

When booting of the UUT 190 is completed, a message (ie, a boot message) output by the UUT 190 may be input as the content of COMP.String. When booting is completed, the UUT 190 outputs a message such as COMP.String, and the power ON / OFF device 100 (or MICOM 140) reads the output message to read PASS or FAIL. Can be determined.

A message or a string (ie, a specific string indicating that booting is successful) for determining whether the UUT 190 is normal after booting may be arbitrarily designated through COMP.String.

If the power ON / OFF device 100 simply performs ON / OFF of the UUT 190, COMP.String may not be used.

The MICOM 140 includes a program that performs ON / OFF of the basic UUT 190, and may execute tests according to timings of the above-described OFF-ON delay, ON-READ delay, and READ-OFF delay.

4 illustrates a screen for inputting setting values through a console according to an embodiment of the present invention.

The three screens 410 to 430 may be screens output to the monitor 180 or the console 240 to input setting values, respectively.

In the first screen 410, the OFF-ON delay is set to 10 seconds.

In the second screen 420, the ON-READ delay is set to 60 seconds.

In the third screen 430, the READ-OFF delay is set to 20 seconds.

5 illustrates a screen showing a booting result of the UUT 190 according to an embodiment of the present invention.

The two screens 510 and 520 may be screens output to the monitor 180 or the console 240 to indicate a booting result, respectively.

In FIG. 5, the number of boot passes (PASS), FAIL, and TOTAL of each of the four UUTs 190 (UUT A, UUT B, UUT C, and UUT D) are shown.

The first screen 510 shows the result after the first ON / OFF test. In the first ON / OFF test, all UUTs 190 passed the boot test. Thus, the pass value of all UUTs 190 is 1, the failure value is 0, and the total value is 1.

The second screen 520 shows the result after the third ON / OFF test. In the third ON / OFF test, all UUTs 190 failed the boot test. Thus, the failure value of all UUTs 190 increases by one. In addition, the total value of all UUTs 190 is three.

6 is a flowchart illustrating a power on / off test method according to an embodiment of the present invention.

In operation 610, the power on / off device 100 turns off the power of the UUT 190.

The MICOM 140 may transmit a control signal of power off to the relay 150, and the relay 150 may turn off the switch 155 according to the control signal of power off. As the relay 150 turns off the switch 155, the power supplied to the AC connector 170 is cut off. Therefore, the UUT 190 is turned off by cutting off the power supplied to the UUT 190.

In operation 615, the power ON / OFF device 100 waits for a predetermined time before turning on the power of the UUT 190 again. The predetermined time may be a delay time according to the OFF-ON delay.

In operation 620, the power on / off device 100 turns on the power of the UUT 190.

The MICOM 140 may transmit a control signal of power ON to the relay 150, and the relay 150 may turn on the switch 155 according to the control signal of power ON. As the relay 150 turns the switch 155 ON, power is supplied to the AC connector 170 again. Therefore, the UUT 190 is turned on by supplying power to the UUT 190 again.

In operation 625, the power on / off device 100 waits for a period of time before receiving a message from the UUT 190. The predetermined time may be a delay time according to the ON-READ delay.

In operation 630, the power on / off device 100 receives a message from the UUT 190.

The message sent from the UUT 190 may be stored in the UART FIFO 120 via the receiver 110.

In operation 640, the power ON / OFF device 100 determines whether a predetermined time elapsed to receive a message from the UUT 190 has elapsed. The predetermined time may be a delay time according to a read-off delay.

The above-described operations 615, 625, and 640 may be performed by the MICOM 140. The MICOM 140 may know the delay time in each of the above-described operations 615, 625, and 640 according to the setting value, and control the operation of the power ON / OFF device 100 according to the delay time. have.

In operation 640, when a predetermined time elapses, the power ON / OFF device 100 performs operation 650, otherwise, performs operation 630 again.

In operation 650, the power ON / OFF device 100 determines whether the UUT 190 is normally booted based on the received message. That is, the power ON / OFF device 100 determines whether the UUT 190 has PASS or FAIL the power ON / OFF test.

The normal booting may be determined according to whether there is a string indicating that the booting of the UUT 190 is successful among the received messages.

The string indicating that the boot was successful may be a specific part of a message output when the UUT 190 successfully boots.

The MICOM 140 reads the message data in the UART FIFO 120 according to the control signal generated by the EPLD 130, and among the read message data, a message (ie, a string) indicating normal booting of the UUT 190 is read. It can be determined whether there is. The message indicating normal booting may be the content of COMP.String.

In operation 660, the power on / off device 100 (eg, MICOM 140) outputs the result of the determination to the monitor 180 or the console 240.

In operation 660, the power on / off device 100 (eg, MICOM 140) checks whether the number of times power on / off has been tested is equal to a predefined value. The power on / off device 100 (e.g., MICOM 140) ends the test if the number of times the power on / off has been tested equals a predefined value (or if the number is greater than or equal to a predefined value), otherwise If not, repeat operation 610.

There may be a plurality of UUT 190 in this embodiment.

Technical contents according to an embodiment of the present invention described above with reference to FIGS. 1 to 5 may be applied to the present embodiment as it is. Therefore, more detailed description will be omitted below.

Method according to an embodiment of the present invention is implemented in the form of program instructions that can be executed by various computer means may be recorded on a computer readable medium. The computer readable medium may include program instructions, data files, data structures, etc. alone or in combination. The program instructions recorded on the medium may be those specially designed and constructed for the present invention or may be available to those skilled in the art of computer software. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tape, optical media such as CD-ROMs, DVDs, and magnetic disks, such as floppy disks. Magneto-optical media, and hardware devices specifically configured to store and execute program instructions, such as ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine code generated by a compiler, but also high-level language code that can be executed by a computer using an interpreter or the like. The hardware device described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above embodiments, and those skilled in the art to which the present invention pertains various modifications and variations from such descriptions. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims, as well as the claims.

100: power on / off device
190: UUT
210: multi-tap
24: console

Claims (23)

A relay that supplies power to the unit under test (UUT) when it is turned on and cuts power to the UUT when it is turned off; And
Microprocessor (MICOM) to turn the relay on or off at a specific time
And the MICOM determines whether a boot test for the UUT succeeds or fails based on a boot message received from the UUT after power is supplied to the UUT. The method of claim 1,
And the MICOM turns on or off the relay at the specific time by applying a control signal to turn the relay on or off at the specific time. The method of claim 1,
And the MICOM determines whether a boot test result for the UUT succeeds or fails depending on whether the boot message includes a string indicating that the boot of the UUT is successful. The method of claim 3,
A string indicating that the boot was successful is a specific part of a message that is output when the UUT successfully boots. The method of claim 1,
And a plurality of UUTs, and the MICOM determines success or failure of a boot check for each of the plurality of UUTs. The method of claim 5,
And the plurality of UUTs are heterogeneous devices. The method of claim 5,
Multi-tap including a plurality of spheres for distributing power supplied from the relay
Further comprising, each of the plurality of UUTs being powered through one of the plurality of spheres. The method of claim 1,
A receiver for receiving a message output from the UUT; And
UART FIFO that stores the message received by the receiver in FIFO (First In First Out)
Further comprising the MICOM reading a message from the FIFO. 9. The method of claim 8,
Electrically Programmable Logic Device (EPLD) for generating a control signal for the MICOM to read the message in the UART FIFO
Further comprising a power ON / OFF device. The method of claim 1,
And the MICOM outputs the result of the determination to the console. The method of claim 1,
AC connector for supplying power to the UUT
Further comprising, the relay switches power supply to the AC connector ON / OFF. The method of claim 1,
And the MICOM repeats ON and OFF of the relay a predetermined number of times at any time period. The method of claim 12,
And the MICOM determines whether the UUT has normally booted at every ON and OFF of the relay. The method of claim 1,
And the MICOM stores, as a log file, a boot failure during execution of which part of the program of the UUT. The method of claim 1,
The MICOM operates according to a setting value, wherein the setting value is a delay time until the UUT turned off, a delay time until the UUT receives the message from the UUT after the UUT is turned on, and from the UUT. A power on / off device comprising one or more of the times for monitoring the predefined strings that are output. 16. The method of claim 15,
And the setting value is input to the MICOM via a console. Turning off the power of the UUT;
Turning on the power of the UUT;
Receiving a message from the UUT; And
Determining whether the UUT is normally booted based on the message
Including, the power on / off test method. 18. The method of claim 17,
Waiting for a predetermined time before turning on the power of the UUT again; And
Waiting for a predetermined time before receiving the message from the UUT
Further comprising, the power ON / OFF test method. 18. The method of claim 17,
Determining whether a predetermined time defined to receive the message from the UUT has elapsed
Further comprising, the power ON / OFF test method. 18. The method of claim 17,
The normal booting or not is determined according to whether there is a string indicating that the booting of the UUT is successful. 21. The method of claim 20,
A string indicating that the boot was successful is a specific part of a message that is output when the UUT successfully boots. 18. The method of claim 17,
Outputting the result of the determination to the console
Further comprising, the power ON / OFF test method. 18. The method of claim 17,
An operation that checks whether the number of times the power ON / OFF has been tested is equal to a predefined value.
Further comprising, the power ON / OFF test method.

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