CN204440641U - A kind of radio-frequency (RF) remote testing apparatus - Google Patents

Abstract

The utility model discloses a kind of radio-frequency (RF) remote testing apparatus.This radio-frequency (RF) remote testing apparatus comprises body, for simulating the click portion of the button of pressing radio-frequency (RF) remote, for the test fixture that radio frequency telepilot positions, for receiving the rf signal reception portion of the radiofrequency signal sent with the radio-frequency (RF) remote of its pairing, for controlling the central control processing unit of radiofrequency signal and the display device for showing test results that described click portion works and processes the reception of described rf signal reception portion, described click portion is arranged on described body, described test fixture is arranged on described body, described rf signal reception portion is connected with described central control processing unit, described display device is connected with described central control processing unit.Radio-frequency (RF) remote testing apparatus of the present utility model can automatically be tested by radio frequency telepilot.

Description

A kind of radio-frequency (RF) remote testing apparatus

Technical field

The utility model relates to a kind of radio-frequency (RF) remote testing apparatus, and it especially may be used for testing multiple radio-frequency (RF) remote simultaneously.

Background technology

Along with improving constantly of living standard, the household electrical appliance had in family are on the increase, and consumer also has higher requirement to the distant control function of these household electrical appliances and performance.Radio-frequency (RF) remote, owing to having the advantages such as the more complicated agreement of distance, accessible, low-power consumption, support, progressively will replace traditional infrared remote control mode.In consumer electronics sector, radio-frequency (RF) remote can be esthetically acceptable to the consumers very soon by the attraction as a very cruel very fashion.Traditionally, when detecting radio-frequency (RF) remote, general several buttons by artificial pressing telepilot, and judge test result artificially, it needs a large amount of artificial, and detection speed is slow, is difficult to realize robotization batch testing.

Utility model content

The purpose of this utility model is, provide a kind of radio-frequency (RF) remote testing apparatus, it can automatically be tested telepilot.

The utility model is achieved through the following technical solutions: a kind of radio-frequency (RF) remote testing apparatus, it is characterized in that comprising body, for simulating the click portion of the button of pressing radio-frequency (RF) remote, for the test fixture that radio frequency telepilot positions, for receiving the rf signal reception portion of the radiofrequency signal sent with the radio-frequency (RF) remote of its pairing, for controlling the central control processing unit of radiofrequency signal and the display device for showing test results that described click portion works and processes the reception of described rf signal reception portion, described click portion is arranged on described body, described test fixture is arranged on described body, described rf signal reception portion is connected with described central control processing unit, described display device is connected with described central control processing unit.

As the further improvement of technique scheme, described radio-frequency (RF) remote testing apparatus also comprises the image test section of the image of the display screen display for taking radio-frequency (RF) remote, and described image test section is connected with described central control processing unit.

As the further improvement of technique scheme, described body comprises upper frame body and belly board, and described display device is arranged on described upper frame body, and described test fixture is arranged on described belly board.

As the further improvement of technique scheme, the quantity of described test fixture is two, described radio-frequency (RF) remote testing apparatus also comprises for driving described click portion along the X-axis drive division of X-axis movement, for driving a test fixture in two test fixtures along the first Y-axis drive division of Y-axis movement, for driving another test fixture in two test fixtures along the second Y-axis drive division of Y-axis movement with for driving described click portion along the Z axis drive division of Z axis movement, X-axis drive division, first Y-axis drive division, second Y-axis drive division is all connected with described central control processing unit with Z axis drive division.

As the further improvement of technique scheme, described test fixture comprises opto-electronic receiver plate for installing described rf signal reception portion and for radio-frequency (RF) remote being positioned to just to the positioning component in described rf signal reception portion, the quantity in described rf signal reception portion is multiple, and the quantity in described rf signal reception portion is corresponding with the quantity of radio-frequency (RF) remote.

As the further improvement of technique scheme, described test fixture also comprises simulated battery assembly, described simulated battery assembly comprises underframe and multiple module that powers on, and the module that respectively powers on includes at least one simulated battery, and at least one simulated battery described is arranged on described underframe.

As the further improvement of technique scheme, described radio-frequency (RF) remote testing apparatus also comprises for sending standard radio frequency signal to the emission of radio frequency signals portion of radio-frequency (RF) remote, described emission of radio frequency signals portion is arranged on the front of radio-frequency (RF) remote, and described emission of radio frequency signals portion is connected with described central control processing unit.

As the further improvement of technique scheme, described radio-frequency (RF) remote testing apparatus also comprises the current sample portion of working current for gathering radio-frequency (RF) remote, quiescent current, and described current sample portion is connected with described central control processing unit.

Enforcement the beneficial effects of the utility model are: radio-frequency (RF) remote testing apparatus of the present utility model can automatically be tested telepilot.

Accompanying drawing explanation

Fig. 1 is the signal electrical diagram of the radio-frequency (RF) remote testing apparatus according to an embodiment of the present utility model;

Fig. 2 is the schematic perspective view of the radio-frequency (RF) remote testing apparatus of Fig. 1;

Fig. 3 is another schematic perspective view of the radio-frequency (RF) remote testing apparatus of Fig. 1;

Fig. 4 is the front schematic view of the radio-frequency (RF) remote testing apparatus of Fig. 1;

Fig. 5 is the schematic perspective view of the body of the radio-frequency (RF) remote testing apparatus of Fig. 1;

Fig. 6 is the schematic perspective view in the click portion of the radio-frequency (RF) remote testing apparatus of Fig. 1;

Fig. 7 is the front schematic view in the click portion of the radio-frequency (RF) remote testing apparatus of Fig. 1;

Fig. 8 is the side schematic view in the click portion of the radio-frequency (RF) remote testing apparatus of Fig. 1;

Fig. 9 is the schematic perspective view of the test fixture of the radio-frequency (RF) remote testing apparatus of Fig. 1;

Figure 10 is the schematic top plan view of the test fixture of the radio-frequency (RF) remote testing apparatus of Fig. 1;

Figure 11 is the schematic perspective view of the positioning component of the test fixture of the radio-frequency (RF) remote testing apparatus of Fig. 1;

Figure 12 is another schematic perspective view of the positioning component of the test fixture of the radio-frequency (RF) remote testing apparatus of Fig. 1;

Figure 13 is the schematic perspective view of the simulated battery assembly of the test fixture of the radio-frequency (RF) remote testing apparatus of Fig. 1;

Figure 14 is another schematic perspective view of the simulated battery assembly of the test fixture of the radio-frequency (RF) remote testing apparatus of Fig. 1;

Figure 15 is the schematic perspective view of the first simulated battery of the simulated battery assembly of the test fixture of the radio-frequency (RF) remote testing apparatus of Fig. 1;

Figure 16 is another schematic perspective view of the first simulated battery of the simulated battery assembly of the test fixture of the radio-frequency (RF) remote testing apparatus of Fig. 1;

Figure 17 is the schematic perspective view of a part for the test fixture of the radio-frequency (RF) remote testing apparatus of Fig. 1, and it removes positioning component and simulated battery assembly;

Figure 18 is another schematic perspective view of a part for the test fixture of the radio-frequency (RF) remote testing apparatus of Fig. 1, and it removes positioning component and simulated battery assembly;

Figure 19 is the schematic perspective view of the adjuster bar 342 of the forestock plate height governor motion of the test fixture of the radio-frequency (RF) remote testing apparatus of Fig. 1;

Figure 20 is the signal electrical diagram of the radio-frequency (RF) remote testing apparatus according to another embodiment of the present utility model;

Figure 21 is the process flow diagram of the telepilot method of testing according to an embodiment of the present utility model;

Figure 22 is the Facad structure schematic diagram of the image test section of the radio-frequency (RF) remote testing apparatus of Fig. 1;

Figure 23 is the Facad structure schematic diagram of the opto-electronic receiver plate on the test fixture of the radio-frequency (RF) remote testing apparatus of Fig. 1.

Embodiment

Below in conjunction with accompanying drawing, embodiment of the present utility model is further detailed.

As depicted in figs. 1 and 2, radio-frequency (RF) remote testing apparatus 1000 comprises body 100, click portion 200, test fixture 300, central control processing unit 400, rf signal reception portion 520, display device 600, pointing input device 700, supply unit 800 and memory storage 900.Radio-frequency (RF) remote testing apparatus 1000 is for testing multiple (for can test two groups simultaneously in the present embodiment, often organizing 4 8) radio-frequency (RF) remote (being hereinafter also called for short telepilot) simultaneously totally.Click portion 200, test fixture 300, rf signal reception portion 520 and display device 600 are arranged on body 100.Central control processing unit 400, supply unit 800 and memory storage 900 can be arranged on body 100, also can be arranged on other the suitable positions outside body 100.In the present embodiment, pointing input device 700 comprises keyboard 710 and mouse 720.

As shown in Figure 3, body 100 is table type structure, and bottom is provided with leg and roller, is convenient to fixing and carrying.Body 100 comprises upper frame body 102, belly board 104 and lower frame body 106.Upper frame body 102, belly board 104 and lower frame body 106 set gradually in the vertical direction.Upper frame body 102 can rotate up by 2 hinges 110 top being openly arranged on body 100.Belly board 104 is positioned at the middle part of body 100.Belly board 104 is the platforms arranging 2 test fixtures 300.Belly board 104 is provided with 2 work nests 114.2 test fixtures 300 are movably located in 2 work nests 114 respectively.Click portion 200 is positioned at the top of belly board 104, and click portion 200 is positioned at below upper frame body 102.The below of belly board 104 is lower frame body 106.The electrical structure etc. of radio-frequency (RF) remote testing apparatus 1000 is accommodated in lower frame body 106.The bottom of belly board 104 is provided with keyboard support 108.Keyboard 710 and mouse 720 are placed on keyboard support 108, and handled easily person uses.

As shown in Figures 1 to 5, upper frame body 102 is formed with cavity 112 in the front of body 100.Display device 600 is arranged in cavity 112.In addition, upper frame body 102 is fixed with shield glass cover 116, for the protection of display device 600.By upwards overturning upper frame body 102, upper frame body 102 can be entered inner, carrying out the operations such as maintenance.And by being arranged in cavity 112 by display device 600, handled easily person observes the information in display device 600, meets ergonomics.

Central control processing unit 400 is by CPU (Central Processing Unit, CPU (central processing unit)) and carry out the formations such as the IO interface of the transmitting-receiving of various signal with each parts be electrically connected to each other.Central control processing unit 400 is electrically connected with click portion 200, test fixture 300, rf signal reception portion 520, display device 600, pointing input device 700, supply unit 800 and memory storage 900 etc., carries out the control of each parts and the transmitting-receiving of signal.Central control processing unit 400 is responsible for the action control of the entirety of radio-frequency (RF) remote testing apparatus 1000.Memory storage 900 such as comprises ROM (Read Only Memory ROM (read-only memory)), RAM (RandomAccess Memory random access memory).Wherein, ROM stores the working routine etc. of telepilot picture, the standard message content of telepilot, the standard picture of telepilot, the groundwork of radio-frequency (RF) remote testing apparatus 1000.RAM is used as the perform region etc. of radio-frequency (RF) remote testing apparatus 1000.Central control processing unit 400 can be embodied as and be made up of computing machine, customization function module, PLC, single-chip microcomputer etc.

As shown in Figure 6 to 8, click portion 200, for simulating the button of staff pressing telepilot, realizes robotization pressing keys.Click portion 200 is arranged on directly over test fixture 300 movably.In the illustrated embodiment, click portion 200 comprise principal point tap the head 202 and auxiliary point tap the head 204.Principal point tap the head 202 and auxiliary point 204 formation, one group of point of tapping the head tap the head.In the illustrated embodiment, click portion 200 comprises four groups of points and taps the head.Often group point is tapped the head for clicking a telepilot.In the illustrated embodiment, principal point tap the head 202 and auxiliary point tap the head 204 by air cylinder driven.Principal point tap the head 202 and auxiliary point tap the head 204 click part be colloid, available protecting remote controller key.Principal point tap the head 202 and auxiliary point tap the head and 204 regulate pressing force by air pressure or spring.Auxiliary point tap the head 204 position can regulate.Tap the head 204 by principal point 202 and 2 auxiliary points of tapping the head, can realize simultaneously or successively pressing three buttons.Principal point tap the head 202 with auxiliary point tap the head 204 have dynamics adjustable, contact the feature that thin-skinned, glue head size easily switches.

As shown in Figure 5,2 test fixtures 300 are movably located in 2 work nests 114 respectively.As shown in Fig. 9 to Figure 19, test fixture 300 comprises positioning component 310, simulated battery assembly 320, front and back adjustable track 330, front supporting plate 302, forestock plate height governor motion 340, opto-electronic receiver plate 304, rear supporting plate 350 and base 360.

Positioning component 310, simulated battery assembly 320, front supporting plate 302, rear supporting plate 350 are modular constructions, as the case may be, can remove from test fixture 300.

Positioning component 310, simulated battery assembly 320 can be installed movably forward and backward along front and back adjustable track 330.Front supporting plate 302 can be installed up or down.Opto-electronic receiver plate 304 is arranged on the front end of test fixture 300.Described opto-electronic receiver plate 304 is for installing described rf signal reception portion 520.Described positioning component 310 is for being positioned to multiple telepilot just to described rf signal reception portion 520.The quantity in described rf signal reception portion 520 is corresponding with the quantity of telepilot.

Rear supporting plate 350 is arranged on the rear end of test fixture 300.At telepilot from charged pool and when not needing to use simulated battery assembly 320 to power, or when telepilot is oversize, rear supporting plate 350 pairs of telepilots can be used to be fixed.Base 360 is for carrying above-mentioned each component of each test fixture 300.

As shown in figure 17, in the left and right sides of test fixture 300, be respectively arranged with front and back adjustable track 330.Front and back adjustable track 330 has gathering sill 306.Positioning component 310, simulated battery assembly 320 can move along gathering sill 306 respectively, to regulate the position on positioning component 310, simulated battery assembly 320 fore-and-aft direction.The two ends of positioning component 310, the two ends of simulated battery assembly 320 are tightened on front and back adjustable track 330 respectively by knob, can ensure that positioning component 310, simulated battery assembly 320 in the lateral direction can not deflections.

As shown in figure 11, positioning component 310 the first positioning strip 312, second positioning strip 313, the 3rd positioning strip 314 that comprise base plate 311 and be arranged in order in the longitudinal direction.First positioning strip 312, second positioning strip 313, the 3rd positioning strip 314 can movably be arranged on base plate 311.In another specific embodiment, the first positioning strip 312, the 3rd positioning strip 314 are fixed on base plate 311, and the second positioning strip 313 can movably be arranged on base plate 311.First positioning strip 312, second positioning strip 313, the 3rd positioning strip 314 are respectively arranged with the column upwards extended.Specifically, the first positioning strip 312 is provided with four the first columns 319 upwards extended.Second positioning strip 313 is provided with four the second columns 317 upwards extended.3rd positioning strip 314 is provided with four the 3rd columns 318 upwards extended.

In preferred embodiment of the present utility model, the 3rd column 318 aligns with the first column 319, by mobile second column 317, positions telepilot.In the embodiment shown in fig. 12, the second positioning strip 313 is driven by positioning cylinder 316, can move left and right.Positioning cylinder 316 is controlled by central control processing unit 400.When setup test or test complete, central control processing unit 400 sends unlock signal to positioning cylinder 316, and positioning cylinder 316 drives the second positioning strip 313 to move towards the direction of unclamping telepilot.In test process, central control processing unit 400 sends locking signal to positioning cylinder 316, and positioning cylinder 316 drives the second positioning strip 313 to move towards the direction of clamping telepilot.

As is illustrated by figs. 11 and 12, each telepilot is fixedly clamped by first column 319, the 3rd column 318 and second column 317 3 place.In the embodiment shown in fig. 11, a positioning component 310 can fix four telepilots.

Although in the embodiment shown in fig. 11, manually regulate the position of the second positioning strip 313, also automatically can be regulated the position of the second positioning strip 313 by the drive unit such as cylinder, motor.

As shown in Figure 13 to Figure 16, simulated battery assembly 320 comprises underframe 321 and four modules 322 that power on.The module 322 that respectively powers on includes at least one simulated battery.The profile of simulated battery is substantially identical with actual battery.In the present embodiment, the module 322 that respectively powers on includes the first simulated battery 323 and the second simulated battery 324.The module 322 that respectively powers on has width adjustment mechanism 327 and structure of adjusting length 328.By width adjustment mechanism 327, the width of the module 322 that respectively powers on can be changed, adapt to the battery of the different in width such as No. 5 batteries, No. 7 batteries.The length of the module 322 that respectively powers on can be changed by structure of adjusting length 328, adapt to the battery of the different lengths such as No. 5 batteries, No. 7 batteries.

As shown in figure 15, width adjustment mechanism 327 is for being arranged on the horizontal elongated slot 327 on the first simulated battery 323.Horizontal elongated slot 327 extends in the lateral direction.By changing the position in the lateral direction of the first simulated battery 323 on underframe 321, and utilize screw to pass horizontal elongated slot 327, first simulated battery 323 is positioned on underframe 321, the width between the first simulated battery 323 and the second simulated battery 324 can be regulated, adapt to the battery compartment of the telepilot of different in width.

As shown in figure 13, structure of adjusting length 328 is for being arranged on the longitudinal elongated slot 328 on the second simulated battery 324.Longitudinal elongated slot 328 extends in the longitudinal direction.By changing the position in the longitudinal direction of the second simulated battery 324 on underframe 321, and utilize screw to pass longitudinal elongated slot 328, second simulated battery 324 is positioned on underframe 321, the relative position on the fore-and-aft direction between the first simulated battery 323 and the second simulated battery 324 can be regulated, adapt to the battery compartment of the telepilot of different length.

First simulated battery 323 and the second simulated battery 324 all have the cylinder that powers on, front electrode and rear electrode.For the first simulated battery 323, the cylinder that powers on, front electrode and rear electrode are described.As shown in figure 15, the first simulated battery 323 all has the cylinder 325 that powers on, electrode 326.Power on before and after cylinder 325 and be connected to electrode 326.When needing the parameter such as quiescent current, dynamic current measuring telepilot, under the power exported by not shown source of the gas, the cylinder 325 that powers on makes electrode 326 eject, as shown in figure 15.When not needing the parameter such as quiescent current, dynamic current measuring telepilot, under the power exported by not shown source of the gas, the cylinder 325 that powers on utilizes negative pressure to be sucked by electrode 326.

As mentioned above, front supporting plate 302 can be installed up or down.As shown in Figures 17 to 19, regulated the height of front supporting plate 302 by forestock plate height governor motion 340, make the key face of telepilot be horizontality as far as possible.As shown in Figures 17 to 19, the bar shaped gear 346 that forestock plate height governor motion 340 comprises adjuster bar 342, is arranged at cylindrical gear 344 on adjuster bar 342, engages with cylindrical gear 344, is arranged on the adjusting knob 349 of adjuster bar 342 end.The upper end of bar shaped gear 346 is fixedly connected with front supporting plate 302 by screw.Forestock plate height governor motion 340 has three pairs of cylindrical gears 344 and bar shaped gear 346, stably can regulate the height of front supporting plate 302 thus.End 348 clamping of adjusting knob 349 and adjuster bar 342.Although in the present embodiment, the module 322 that respectively powers on includes 2 simulated batteries, and the utility model is not limited thereto, and the module that respectively powers on also can comprise the simulated battery of, three or other right quantities.

As shown in Figure 1, by test fixture 300,4 telepilots are being positioned, after being matched with multiple radio-frequency (RF) remote respectively in multiple rf signal reception portion, central control processing unit 400 controls click portion 200, makes click portion 200 simulate the button of pressing telepilot; Rf signal reception portion 520 receives the radiofrequency signal that telepilot sends, central control processing unit 400 receives the detection signal (radiofrequency signal namely to be detected) that described rf signal reception portion 520 sends, parse according to RF communication protocol the message content that the detection signal that received by rf signal reception portion comprised by central control processing unit, by central control processing unit, message content to be measured and the message content prestored are compared; Then in display device 600, show the result of comparison.

When being matched with multiple radio-frequency (RF) remote respectively in multiple rf signal reception portion, such as, can adopt power-down mode, pressing specific keys mode, signal shielding box mode, minimum distance matching method and password matching method etc.

Described radio-frequency (RF) remote testing apparatus 1000 also comprises X-axis drive division 210, first Y-axis drive division 230, second Y-axis drive division 240 and Z axis drive division 220.

As shown in Figure 7 and Figure 8, described X-axis drive division 210 moves along X-axis for driving click portion 200.Described Z axis drive division 220 moves along Z axis for driving click portion 200.Wherein, X-direction is left and right directions; Y direction is fore-and-aft direction; Z-direction is above-below direction.As shown in Figure 7 and Figure 8, X-axis drive division 210 comprises X-axis CD-ROM drive motor 212, X-axis drives belt 214, X-axis guide rail 216.Wherein, click portion 200 drives belt 214 to be connected with Z axis drive division 220 entirety with X-axis.Under the driving of X-axis CD-ROM drive motor 212, click portion 200 and Z axis drive division 220 drive belt 214 to drive by X-axis, slide along X-axis guide rail 216.As shown in Figure 7 and Figure 8, Z axis drive division 220 comprises Z axis CD-ROM drive motor 222, Z axis drives belt 224, Z axis guide rail 226.Click portion 200 and Z axis drive belt 224 to be connected.Under the driving of Z axis CD-ROM drive motor 222, click portion 200 drives belt 224 to drive by Z axis, slides along Z axis guide rail 226.The motor driver of X-axis CD-ROM drive motor, Z axis CD-ROM drive motor is connected with central control processing unit 400.Central control processing unit 400 controls the motor driver of X-axis CD-ROM drive motor, Z axis CD-ROM drive motor.

First Y-axis drive division 230, second Y-axis drive division 240 is arranged on below the base 360 of 2 test fixtures 300 respectively, described first Y-axis drive division 230 moves along Y-axis for driving a set of test fixture in two test fixtures, and described second Y-axis drive division 240 moves along Y-axis for driving the another set of test fixture in two test fixtures.First Y-axis drive division 230, second Y-axis drive division 240 also comprises CD-ROM drive motor respectively, drives belt and guide rail, and its structure and principle of work do not repeat.

Although in the illustrated embodiment, first Y-axis drive division 230, second Y-axis drive division 240 moves in Y-axis for driving 2 test fixtures 300, but the utility model is not limited thereto, the first Y-axis drive division 230, second Y-axis drive division 240 also can drive click portion 200 to move along Y-axis.As long as when meeting spirit of the present utility model, changing click portion 200 and the relative position of test fixture 300, pressing the different key of the telepilot be positioned on test fixture 300 fast.

In addition, as shown in figure 20, described radio-frequency (RF) remote testing apparatus 1000A also comprises image test section 540.This testing image for taking the testing image that telepilot shows, and is sent to described central control processing unit 400 by described image test section 540.As shown in figure 22, image test section 540 is arranged in back up pad 542.Back up pad 542 is arranged in upper frame body 102, and back up pad 542 is arranged on the top of test fixture 300.In the present embodiment, back up pad 542 is installed with 4 image test sections 540.But the utility model is not limited thereto, such as, 2 image test sections can be arranged in back up pad 542 in the mode moved around.This testing image and standard picture are compared by central control processing unit 400.Image test section 540 adopts industrial camera, and pixel is preferably the industrial camera of more than 5,000,000 pixels.Image test section 540 can be such as CCD camera.Image test section 540 is arranged on the top of test fixture 300, for taking picture and text and the numeral of the display screen display of telepilot.Such as when detection has the air-conditioning remote control of display screen, when pressing a certain button, the corresponding change of display information on display screen.Now, while detected the radiofrequency signal of the transmitting of telepilot to be measured by rf signal reception portion 520, while taken the testing image that telepilot shows by image test section 540, this testing image and standard picture are compared by central control processing unit 400, judge whether display information on display screen correct, Multi strokes on display screen, lack stroke, secretly to draw, the defect such as light leak.

As shown in figure 20, described radio-frequency (RF) remote testing apparatus 1000A also comprises emission of radio frequency signals portion 530.Described emission of radio frequency signals portion 530 is for sending standard radio frequency signal to radio-frequency (RF) remote to be detected.Emission of radio frequency signals portion 530 is for detecting the learning functionality of study remote controller.As shown in figure 23, in the present embodiment, on opto-electronic receiver plate 304, rf signal reception portion 520 is configured in below emission of radio frequency signals portion 530.

As shown in figure 21, the utility model also provides a kind of radio-frequency (RF) remote method of testing, and it is realized by above-mentioned radio-frequency (RF) remote testing apparatus.

Described radio-frequency (RF) remote method of testing comprises the following steps:

S101, matches with multiple radio-frequency (RF) remote respectively by multiple rf signal reception portion;

S102, by the button of click portion simulation pressing radio-frequency (RF) remote;

S103, the radiofrequency signal of being launched by rf signal reception portion received RF telepilot, parses by central control processing unit the message content that the detection signal that received by rf signal reception portion comprised;

S104, is compared message content to be measured and the message content prestored by central control processing unit;

S105, by the testing image of the display screen display of image test section shooting telepilot, compares this testing image and the standard picture prestored; With

S106, by the result of display device display comparison.

In above-mentioned telepilot method of testing, usually can press different buttons, repeatedly above-mentioned step S101 is to step S106.In the process of each pressing keys, be likely pressing button, also may press 2 or multiple button simultaneously.

In step s 107, if judge not need to press more key, then end is tested.If need to continue the more key of pressing, then repeat step S101 to step S106.

In the exemplary gatherer process of standard message content, rf signal reception portion 520 receives the radiofrequency signal of each button of telepilot engineering prototype, then, signal is sent into central control processing unit 400 and carry out dissection process, so that it is for subsequent use to make standard message content during follow-up test.

Following important parameter can be shown on display 600: 1. the message content of tested radio-frequency (RF) remote and the difference percentage (telepilot as multiple in multiple channel test then divides multiple passage to show) of the standard message content prestored; 2. show the correctness of each coding in the message content of tested radio-frequency (RF) remote, errors excepted position, then distinguish on a display screen with redness and show; 3. show the item of corresponding bad button, or the position of the bad button of graphic software platform; 4. telepilot as multiple in multiple channel test, then can bad passage corresponding to graphic software platform, i.e. the location number of bad telepilot; 5. show the dynamic current of each telepilot; 6. show the quiescent current of each telepilot; 7. show the image of the display screen display of each telepilot.

Implement radio-frequency (RF) remote testing apparatus of the present utility model, at least there is following beneficial effect:

1. can appoint computer easily and under user-programmable controls, fully automatically test four or many telepilots with realizing hyperchannel simultaneously, and the earth improves production efficiency, effectively save artificial.(relative traditional-handwork test, can save 3 to 4 Manufacturing Workers.)

2. this utility model example also realizes automatic keying action, the automatic test action realized under computer with application click portion, and greatly can improve the reliability of quality control in production.

3. this utility model example also applies visual programming simultaneously, can user-friendlyly use, and shares programming and test data.

4. this utility model example is completed process and the display of test data by computer, and the earth simplifies the structure of production equipment, is easy to maintenance and maintenance.

5., because adopt the mode of message comparison to test the push button signalling of telepilot, the test of the compatible most telepilot of this utility model example, greatly reduces the spending of device upgrade that manufacturer brings because of replacement of products or upgrading or increasing purchase.

6. apply the remote controller detection method that the utility model is researched and developed, cost is low, easily produces, and the popularization that greatly can facilitate automated production in telepilot production, with universal, produces obvious social benefit.

In description of the present utility model, it is to be appreciated that term " first ", " second " etc. are only for describing object, and instruction or hint relative importance can not be interpreted as.In description of the present utility model, it should be noted that, unless otherwise clearly defined and limited, term " is connected ", " connection " should be interpreted broadly, such as, can be fixedly connected with, also can be removably connect, or connect integratedly; Can be mechanical connection, also can be electrical connection; Can be directly be connected, also indirectly can be connected by intermediary.For the ordinary skill in the art, concrete condition the concrete meaning of above-mentioned term in the utility model can be understood.In addition, in description of the present utility model, except as otherwise noted, the implication of " multiple " is two or more.

Describe and can be understood in process flow diagram or in this any process otherwise described or method, represent and comprise one or more for realizing the module of the code of the executable instruction of the step of specific logical function or process, fragment or part, and the scope of preferred implementation of the present utility model comprises other realization, wherein can not according to order that is shown or that discuss, comprise according to involved function by the mode while of basic or by contrary order, carry out n-back test, this should understand by embodiment person of ordinary skill in the field of the present utility model.

Although illustrate and described embodiment of the present utility model, those having ordinary skill in the art will appreciate that: can carry out multiple change, amendment, replacement and modification to these embodiments when not departing from principle of the present utility model and aim, scope of the present utility model is by claim and equivalents thereof.

Claims (8)

1. a radio-frequency (RF) remote testing apparatus, it is characterized in that comprising body, for simulating the click portion of the button of pressing radio-frequency (RF) remote, for the test fixture that radio frequency telepilot positions, for receiving the rf signal reception portion of the radiofrequency signal sent with the radio-frequency (RF) remote of its pairing, for controlling the central control processing unit of radiofrequency signal and the display device for showing test results that described click portion works and processes the reception of described rf signal reception portion, described click portion is arranged on described body, described test fixture is arranged on described body, described rf signal reception portion is connected with described central control processing unit, described display device is connected with described central control processing unit.

2. radio-frequency (RF) remote testing apparatus according to claim 1, it is characterized in that, described radio-frequency (RF) remote testing apparatus also comprises the image test section of the image of the display screen display for taking radio-frequency (RF) remote, and described image test section is connected with described central control processing unit.

3. radio-frequency (RF) remote testing apparatus according to claim 1, is characterized in that, described body comprises upper frame body and belly board, and described display device is arranged on described upper frame body, and described test fixture is arranged on described belly board.

4. radio-frequency (RF) remote testing apparatus according to claim 1, it is characterized in that, the quantity of described test fixture is two, described radio-frequency (RF) remote testing apparatus also comprises for driving described click portion along the X-axis drive division of X-axis movement, for driving a test fixture in two test fixtures along the first Y-axis drive division of Y-axis movement, for driving another test fixture in two test fixtures along the second Y-axis drive division of Y-axis movement with for driving described click portion along the Z axis drive division of Z axis movement, X-axis drive division, first Y-axis drive division, second Y-axis drive division is all connected with described central control processing unit with Z axis drive division.

5. radio-frequency (RF) remote testing apparatus according to claim 1, it is characterized in that, described test fixture comprises opto-electronic receiver plate for installing described rf signal reception portion and for radio-frequency (RF) remote being positioned to just to the positioning component in described rf signal reception portion, the quantity in described rf signal reception portion is multiple, and the quantity in described rf signal reception portion is corresponding with the quantity of radio-frequency (RF) remote.

6. radio-frequency (RF) remote testing apparatus according to claim 5, it is characterized in that, described test fixture also comprises simulated battery assembly, described simulated battery assembly comprises underframe and multiple module that powers on, the module that respectively powers on includes at least one simulated battery, and at least one simulated battery described is arranged on described underframe.

7. radio-frequency (RF) remote testing apparatus according to claim 1, it is characterized in that, described radio-frequency (RF) remote testing apparatus also comprises for sending standard radio frequency signal to the emission of radio frequency signals portion of radio-frequency (RF) remote, described emission of radio frequency signals portion is arranged on the front of radio-frequency (RF) remote, and described emission of radio frequency signals portion is connected with described central control processing unit.

8. radio-frequency (RF) remote testing apparatus according to claim 1, it is characterized in that, described radio-frequency (RF) remote testing apparatus also comprises the current sample portion of working current for gathering radio-frequency (RF) remote, quiescent current, and described current sample portion is connected with described central control processing unit.