CN110824284A - Method and tool for testing expansion base - Google Patents

Abstract

The application discloses a detection method of an expansion base, which is suitable for a fault-removing terminal, and comprises the following steps: driving an automatic terminal plugging module to enable a transmission line to be automatically plugged between a terminal port of an expansion base and a transmission port of a host, wherein the automatic terminal plugging module drives a clamp to clamp the transmission line to move through a stepping motor; after the clamp is driven, the transmission line is driven to be inserted into the transmission port of the host, and a device management module checks whether the expansion base is normally inserted or not; if the docking station has been normally plugged, driving a light source identification module to identify a light signal change of the docking station; receiving an identification result of the light source identification module; and recording the recognition result and outputting a recording file, thereby performing an automatic test on the expansion base.

Description

Method and tool for testing expansion base

Technical Field

The present disclosure relates to the field of docking station detection, and more particularly, to a method for verifying docking station functions by detecting the plugging/unplugging of a terminal of a docking station and a method for operating the same.

Background

In the past, when the test operation is executed, a user needs to observe a lamp number presented after the test, or after the terminal is plugged and pulled manually, a screen displays information to judge whether the test operation passes or not. If the above test is performed in a long time cycle, the user cannot look at the test system (e.g. the docking station) and the light (e.g. the indicator light of the docking station) or the screen of the docking station to be tested for a long time, so that the user cannot know whether the result meets the standard in the test process, and therefore the test result is missed or misjudged.

Disclosure of Invention

In view of the above, the present disclosure is directed to a technique for assisting the above problems and disadvantages, avoiding the occurrence of missed judgment or erroneous judgment, and integrating a light source identification and terminal automatic plugging/unplugging module through a debug terminal (Console) to perform an automatic test on a docking station to be tested and judge a test result.

According to an embodiment of the present invention, a method for detecting a docking station is provided, which is suitable for an error-resilient terminal, the method comprising: driving an automatic terminal plugging module to enable a transmission line to be automatically plugged between a terminal port of the expansion base and a transmission port of a host, wherein the automatic terminal plugging module drives a clamp to clamp the transmission line to move through a stepping motor; after the clamp is driven, driving a light source identification module to identify a lamp number change of the expansion base; receiving a first identification result of the light source identification module; and recording the first recognition result and outputting a recording file.

According to another embodiment of the present invention, a docking station testing fixture is provided, the testing fixture comprising: a row of wrong terminals; a terminal automatic plugging module; a light source identification module; the microcontroller is coupled with the terminal automatic plugging module, the debugging terminal and the light source identification module; the expansion base is provided with a transmission line connected with the expansion base, the microcontroller drives the terminal automatic plugging module to enable the transmission line to be automatically plugged between a terminal port of the expansion base and a transmission port of a host, the terminal automatic plugging module drives a clamp through a stepping motor to clamp the transmission line for moving, and after the clamp is driven, the light source identification module is driven to identify the change of a lamp number of the expansion base, a first identification result of the light source identification module is received, the first identification result is recorded, and a recording file is output.

The invention integrates the automatic terminal plugging module, utilizes the microcontroller to control the expansion of the stepping motor so as to replace the action of manually plugging and unplugging the terminal, and detects the function of the expansion base (DS) after each time of plugging and unplugging the terminal, thereby achieving the aim of automatic test. The light source identification module and the terminal automatic plugging module assist and improve the correctness of all test results, avoid missing judgment or misjudgment caused by careless mistakes of users, record related test data, enable the users to inspect the test results afterwards, provide detailed test records to facilitate debugging, avoid errors in artificial judgment, effectively improve the test quality and improve the test accuracy. The user only needs to connect and set the debugging terminal, the microcontroller, the light source identification module, the terminal automatic plugging module and the expansion base to be tested, and the manual intervention is completely not needed when the test is executed, so that the labor cost is saved.

For a further understanding of the techniques, methods and technical effects of the invention to achieve the stated objectives, it is believed that the objects, features and characteristics of the invention will be more fully understood from the following detailed description of the invention, taken in conjunction with the accompanying drawings, which are included to provide a further understanding of the invention, and are not intended to be limiting.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without undue effort. Wherein:

FIG. 1A shows an embodiment of a docking station testing fixture;

fig. 1B shows a record file related to the recognition result of the light source recognition module according to an embodiment of the invention.

FIG. 1C shows an embodiment of a record file related to the execution status of a transmission port of a host;

FIG. 2 is a flowchart illustrating a docking station detection method according to an embodiment of the present invention;

FIG. 3 is a flow chart of a terminal plugging test according to an embodiment of the present invention;

FIG. 4 is a flowchart illustrating the detection of the signal of the docking station according to an embodiment of the present invention.

Detailed Description

The following description is provided for the embodiments of the docking station detection method and fixture disclosed in the present invention with specific embodiments, and those skilled in the art will understand the advantages and effects of the present invention from the disclosure of the present specification. The invention is capable of other and different embodiments and its several details are capable of modification and various other changes, which can be made in various details within the specification and without departing from the spirit and scope of the invention. The drawings of the present invention are for illustrative purposes only and are not intended to be drawn to scale. The following embodiments will further explain the related art of the present invention in detail, but the disclosure is not intended to limit the scope of the present invention.

It will be understood that, although the terms "first," "second," "third," etc. may be used herein to describe various components or signals, these components or signals should not be limited by these terms. These terms are used primarily to distinguish one element from another element or from one signal to another signal. In addition, the term "or" as used herein should be taken to include any one or combination of more of the associated listed items as the case may be.

The automatic plugging module integrates the light source sensor and the terminal, and judges whether an LED lamp of the expansion base to be tested is lighted or not, senses and processes colors and detects the frequency of lamp signal flicker after the program of the debugging terminal is edited and set; in addition, the automatic terminal plugging module can be integrated, the expansion and contraction of the stepping motor are controlled by using a microcontroller editing program, and the function of the expansion base (DS) is detected after the terminal is plugged and unplugged every time, so that the aim of automatic testing is fulfilled.

Referring to fig. 1A, an docking station detection tool 100 according to an embodiment of the invention is shown. As shown, the docking test fixture 100 is adapted for a host 199, such as an industrial computer or a personal computer, the test fixture 100 includes: a debug terminal (Console) 140; a Docking Station (DS) 130 having a transmission line 132 connected to the Docking Station 130; a terminal automatic plugging module 131; a light source identification module 120; and a Micro Controller Unit (MCU)110 coupled to the automatic terminal plugging/unplugging module 131, the error eliminating terminal 140 and the light source identification module 120. The host 199 further includes a device management module 1991 for checking whether the docking station 130 is normally plugged to the transmission line 132. Thus, FIG. 1A can implement automated testing of a single docking station under test.

In an embodiment, the Micro Controller Unit (MCU)110 may also be coupled to a plurality of terminal auto-plugging modules, docking stations, or light source identification modules to perform an automatic test on a plurality of docking stations simultaneously, which is not limited in the present invention.

Specifically, in the embodiment shown in fig. 1A, the microcontroller 110 drives the automatic terminal plugging module 131 to automatically plug the transmission line 132 between a terminal port 132T of the docking station 130 and a transmission port 132X of the host 199, and the automatic terminal plugging module 131 drives a clamp (not shown) to clamp the transmission line 132 for movement by a stepping motor (not shown).

In one embodiment, one end of the transmission line 132, such as compared to the proximal end of the docking station 130, is plugged into the terminal port 132X of the docking station 130 and secured with a system fastening device (not shown); the other end of the transmission line 132, for example, the far end of the docking station 130, is clamped to the fixture of the stepper motor.

In one embodiment, the microcontroller 110 communicates with the light source identification module 120 through an integrated circuit bus (I2C) interface and controls the stepper motor by Pulse Width Modulation (PWM) to insert the distal end of the transmission line 132 into the transmission port 132X of the host 199 or to extract the transmission line 132 from the transmission port 132X of the host 199.

In the embodiment shown in fig. 1A, after the clamp is driven, the transmission line 132 is driven to be plugged into the transmission port 132X of the host 199, and a device management module 1991 of the host 199 checks whether the docking station 130, the terminal port 132T, the transmission line 132, the transmission port 132X and the host 199 have been plugged into each other to establish a normal electrical connection? If the docking station is normally plugged, the microcontroller 110 drives the light source identification module 120 to identify a light signal change of the docking station 130. In one example, at least one of the light emitting color (RGB), the light emitting color temperature, the light emitting frequency and the illumination of at least one light emitting device (e.g., LED lamp) in the docking station 130 can be identified by the light source identification module 120.

Then, the microcontroller 110 receives a first identification result of the light source identification module 120, records the first identification result, and outputs a record file to the debug terminal 140.

Fig. 1B shows a record file related to the recognition result of the light source recognition module 120 according to an embodiment of the invention. As shown, information on the color temperature, illuminance, color, and the like of the LED lamp measured in the first Cycle (Cycle 1) and the second Cycle (Cycle 2), respectively, is described in the recording file.

In another embodiment, the detecting tool shown in fig. 1A may further include: a Hub (Ethernet Hub)150, wherein the Hub 150 is connected to the host 199 and the debug terminal 140 respectively, so that the debug terminal 140 can obtain the communication result from the microcontroller 110 and the host 199 respectively and generate a log file for analyzing the function of the docking station 130. In one example, a device management module 1991 may be provided to check whether the docking station 130, the terminal port 132T, the transmission line 132, the transmission port 132X and the host 199 are normally electrically connected by plugging, and notify the microcontroller 110 of the result through the hub 150 and the debug terminal 140. When the microcontroller 110 knows that the docking station 130 is normally plugged, the microcontroller 110 drives the light source identification module 120 to identify a light signal change of the docking station 130.

FIG. 1C shows an embodiment of a log file related to the execution status of the port 132X of the host 199. As shown, the record file records the execution status of the transmission port 132X when the transmission line 132 is inserted into the transmission port 132X of the host 199 or when the transmission line 132 is pulled out from the transmission port 132X of the host 199 respectively measured in the first cycle and the second cycle, wherein the execution status includes the Resolution (Resolution) data outputted by the screen of the docking station 130 and the output of the Device management (Device Manager) module.

Referring to fig. 1A and fig. 2, fig. 2 is a flowchart illustrating a docking station detection method according to an embodiment of the invention. As shown, the detection method is suitable for the debugging terminal 140, the debugging terminal 140 and the host 199 to install a control panel program respectively, execute the control panel program on the debugging terminal 140, select the test items to be executed, and set the management parameters of the light source identification module 120, the terminal automatic plugging module 131 and the power supply in the control panel program respectively. The method comprises the following steps: in step S201, a terminal automatic plugging module 131 can be driven to automatically plug a transmission line 132 between a terminal port 132T of the docking station 130 and a transmission port 132X of the host 199, wherein the terminal automatic plugging module 131 drives a clamp to clamp the transmission line 132 for movement by a further motor. In one example, before the transmission line 132 is moved, the relative positions of the terminal auto-plug module 131 and the host 199 are corrected.

In one embodiment, the I/O port of the docking station 130 is plugged into the transmission line 132 of the automatic plugging/unplugging module 131.

In step S203, after the fixture is driven by the stepping motor, the transmission line 132 is driven to be plugged into the transmission port 132X of the host 199, and a device management module 1991 of the host 199 checks whether the docking station 130, the terminal port 132T, the transmission line 132, the transmission port 132X and the host 199 are normally electrically connected by plugging. If it is determined that the docking station 130 is normally plugged, the microcontroller 110 drives a light source identification module 120 to identify a light signal change of the docking station 130. In one example, the device management module 1991 checks whether the docking station 130, the terminal port 132T, the transmission line 132, the transmission port 132X and the host 199 have been plugged to establish a normal electrical connection, and notifies the result to the microcontroller 110 through the hub 150 and the debug terminal 140. When the microcontroller 110 knows that the docking station 130 is normally plugged, the microcontroller 110 drives the light source identification module 120 to identify a light signal change of the docking station 130.

In one embodiment, the debugging terminal 140 controls the operation of the terminal automatic plugging module 131 and the light source identification module 120 through a Microcontroller (MCU), the microcontroller 110 is connected to a Universal Serial Bus (USB) port of the debugging terminal 140 through a USB cable, and the light source identification module 120 and the terminal automatic plugging module 131 are respectively connected to the microcontroller 110. In one example, the micro-controller 110 communicates with the light source identification module 120 via an integrated circuit bus (I2C), and controls the stepping motor via Pulse Width Modulation (PWM) to perform the testing of the docking station 130 under test. The light source identification module 120 identifies the lamp number change through a color sensor.

In one embodiment, the light signal is changed to at least one of the color, color temperature, flicker frequency and illumination of at least one light emitting device (such as an LED lamp) in the docking station 130.

In step S205, the microcontroller 110 receives a first recognition result of the light source recognition module 120.

In step S207, the micro-controller 110 records the first identification result and outputs a record file to the debug terminal 140.

In one embodiment, the microcontroller 110 drives the terminal automatic plugging module 131 to automatically plug the transmission line 132 between the terminal port 132T of the docking station 130 and the transmission port 132X of the host 199; the microcontroller 110 drives the light source identification module 120 to identify the light signal change of the docking station 130; the microcontroller 110 receives a second recognition result of the light source recognition module 120; and the micro-controller 110 records the second recognition result, updates the recording file and outputs the recording file to the debugging terminal 140.

In an embodiment, the implementation of fig. 2 may still further include: network communication is performed by connecting to a host 199 via a Hub (Ethernet Hub) 150; obtaining an execution status of the host 199 via the hub 150; displaying an execution state; recording the execution state in a recording file; based on the log file, the debug terminal 140 can analyze and determine whether the detection operation of the docking station 130 is passed.

In an embodiment, the automatic terminal plugging module 131 drives a clamp to clamp the transmission line 132 through a stepping motor, for example, a DP/HDMI/VGA/DVI terminal to plug and unplug the host 199, after the insertion of the transmission line 132 is completed, the device management module 1991 checks that the connection among the docking station 130, the transmission line 132 and the host 199 is normal, and then the light source identification module 120 detects the light number of the docking station 130.

If the transmission line 132 is a VGA terminal, the lamp signal presents a orange lamp when in standby, and a screen of the docking station 130 turns into a blue lamp when being lighted; after the light source identification module 120 detects that the light signal changes to the blue light, the host 199 collects the Resolution (Resolution) data outputted from the screen to detect that the screen really has an output signal. The microcontroller 110 issues a removal instruction to the terminal automatic plugging module 131, and after the terminal removal operation is completed, the light source identification module 120 detects that the light signal is changed from blue to orange. Thus, after completing a single test with double confirmation, the control panel program can also set the Cycle (Cycle) number or time to perform the Cycle test. Thus, it can be confirmed whether the detection operation of the VGA terminal on the docking station 130 passes.

In another embodiment, the automatic terminal plugging module 131 can drive a clamp to clamp the transmission line 132, such as an RJ-45 network line, to plug and unplug the host 199 via a stepping motor, and the light source identification module 120 detects two lights, i.e., a connection light and a speed light, of the docking station 130, wherein the connection light is orange, and the speed light is not bright when the network speed is 10M; when the network speed is 100M, the speed lamp signal is green; when the network speed is 1G, the speed lamp number presents a red-orange lamp; when the RJ-45 network cable is not inserted, the connection lamp is not on, and the speed lamp is not on.

After the RJ-45 network cable is plugged into the transmission port 132X of the host 199, the light source identification module 120 detects the light signal to ensure that the network connection has reached the set value and the connected light signal is orange (active: flashing/standby: non-flashing); when the network speed is 10M, the speed lamp is not on; when the network speed is 100M, the speed lamp signal is green; and when the network speed is 1G, the speed lamp signal is a red-orange lamp and is normally connected. The microcontroller 110 further issues a pull-down command to the terminal automatic plugging module 131, and after the action of pulling out the RJ-45 network cable is completed, the connection light is not on and the speed light is not on. Thus, after a single test is completed with double confirmation, the control panel program can also set the cycle number or time to perform the repeated detection. Thus, it can be determined whether the detection operation of the RJ-45 network cable on the docking station 130 is passed or not.

Referring to fig. 1A and fig. 3, fig. 3 is a flowchart illustrating a terminal plugging test according to an embodiment of the invention. In step S301, the serial port of the debug terminal 140 is initialized, and the transmission rate (baud rate) of the microcontroller 110 is set.

In step S303, the micro-controller 110 can initialize the position of the stepping motor to facilitate driving a clamp to clamp the transmission line 132 between a terminal port 132T of the docking station 130 and a transmission port 132X of the host 199.

In step S305, the microcontroller 110 receives a command from the debug terminal 140 to drive a terminal automatic plugging module 131 to automatically plug terminals such as a transmission line 132 between a terminal port 132T of the docking station 130 and a transmission port 132X of the host 199, or to plug the transmission line 132 from the transmission port 132X of the host 199 (step S307).

Please refer to fig. 4, which shows a flowchart of the lamp signal detection of the docking station 130 according to an embodiment of the present invention. In step S401, the serial port of the debug terminal 140 is initialized and the transmission rate (baud rate) of the microcontroller 110 is set.

In step S403, the light source identification module 120 identifies at least one of a light emitting color, a light emitting color temperature and an illumination intensity of at least one light emitting element (such as an LED lamp) in the docking station 130.

In step S405, the light source identification module 120 calculates the blinking frequency of the light emitting devices according to the light emitting color and the illumination of the light emitting devices.

In step S407, the micro-controller 110 outputs the information of the light emitting device, such as the light emitting color, the illumination and the blinking frequency, to the error terminal 140 for the subsequent error-checking operation. After the test is completed, the debug terminal 140 can complete the test by viewing the log file.

[ possible technical effects of the embodiment ]

The system combines the light source identification module and the terminal automatic plugging module, integrates the power management mode of an X86 product through a debugging terminal, simulates the situation of a user, and achieves the purposes of full automation, multi-mode multi-task, synchronous or asynchronous terminal plugging and expansion base function test.

The present disclosure integrates a light source sensor and a terminal automatic plugging module. After the program of the debugging terminal is edited and set, whether the LED lamp of the extended base to be tested is lighted or not, color sensing processing and the frequency of lamp signal flicker detection are judged according to the program. In addition, the automatic terminal plugging module can be integrated, the expansion and contraction of the stepping motor are controlled by using a microcontroller editing program, and the function of the expansion base is detected after the terminal is plugged and pulled every time, so that the aim of automatic testing is fulfilled.

In other words, the invention accurately records the result of the test process and the occurrence time point through the light source identification module. The control panel program of the invention has a simple control interface, and is convenient for users to plan the test flow. The manual operation time is saved, the test can be performed only after the host, the microcontroller and the expansion base to be tested are set, the manual operation and the success or failure of the identification are not needed, and all the tests can be completed by the final judgment of the record file. The debugging terminal records the test result and forms a record file, thereby reducing the errors of human judgment and improving the test accuracy.

It should be finally noted that while in the foregoing specification, the present inventive concept has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the present inventive concept as defined by the appended claims.

Claims (10)

1. A method for testing an expansion base, which is suitable for a fault-clearing terminal, the method comprising:

driving a terminal automatic plugging module to enable a transmission line to be automatically plugged between a terminal port of the expansion base and a transmission port of a host, wherein the terminal automatic plugging module drives a clamp to clamp the transmission line to move through a stepping motor;

after the clamp is driven, a light source identification module is driven to identify a lamp number change of the expansion base; receiving a first identification result of the light source identification module; and

and recording the first recognition result and outputting a recording file.

2. The method of claim 1, wherein the method further comprises: driving the terminal automatic plugging module to automatically plug the transmission line between the terminal port of the expansion base and the transmission port of the host;

driving the light source identification module to identify the lamp number change of the extension base;

receiving a second identification result of the light source identification module; and

and recording the second recognition result, updating the record file and outputting the record file.

3. The method according to claim 1 or claim 2, wherein the light signal change is at least one of a light color, a light color temperature, a light flicker rate and an illumination of at least one light emitting element in the docking station.

4. The method as claimed in claim 1, wherein the debugging terminal controls the operation of the terminal automatic plugging module and the light source identification module through a microcontroller, and the light source identification module identifies the change of the light signal through a color sensor.

5. The method of claim 1, wherein after the fixture is actuated and before the light source identification module is actuated to identify the light sign change of the docking station, the method further comprises:

connecting to the host computer through a concentrator;

driving the transmission line to be plugged into the transmission port of the host, and providing a device management module to check whether the expansion base is plugged normally;

if the expansion base is normally plugged, the light source identification module is driven to identify the lamp signal change of the expansion base;

obtaining an execution state of the host through the hub;

displaying the execution state;

recording the execution state in the recording file; and

and analyzing and judging whether the detection of the expansion base passes or not according to the record file.

6. The utility model provides a docking station's detection tool, its characterized in that, detection tool includes:

a row of wrong terminals;

a terminal automatic plugging module;

a light source identification module; and

a microcontroller coupled to the automatic terminal plugging/unplugging module, the error-eliminating terminal and the light source identification module;

the automatic terminal plugging module drives a clamp to clamp the transmission line for movement through a stepping motor, and after the clamp is driven, the light source identification module is driven to identify the lamp number change of the expansion base, receive a first identification result of the light source identification module, record the first identification result and output a record file.

7. The detecting tool according to claim 6, wherein the light source identification module identifies at least one of a light emitting color, a light emitting color temperature, a light emitting blink frequency and an illumination of at least one light emitting element in the docking station.

8. The detecting tool for detecting the rotation of a motor shaft as claimed in claim 6, wherein one end of the transmission line is inserted into the terminal port of the docking station, and the other end of the transmission line is fixed to the fixture of the stepping motor.

9. The detecting tool according to claim 6, wherein the micro-controller communicates with the light source identification module through an integrated circuit bus interface, and controls the stepping motor through a pulse width modulation manner so as to insert the distal end of the transmission line into the transmission port of the host or extract the transmission line from the transmission port of the host.

10. The inspection tool of claim 6, wherein the inspection tool further comprises:

a hub, wherein the hub is connected with the host and the debugging terminal respectively so as to enable the debugging terminal to obtain communication results from the microcontroller and the host respectively and generate a record file;

after the clamp is driven, the transmission line is driven to be inserted into the transmission port of the host, and a device management module of the host checks whether the expansion base is normally inserted or not; if the extension base is normally plugged, the light source identification module is driven to identify the lamp signal change of the extension base.

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