CN202996006U - Laser remote control receiving device - Google Patents

Abstract

The utility model relates to the technical field of electronics, in particular to a laser technical field. A laser remote control receiving device comprises infrared light sensors and a micro-processor system. The number of the infrared light sensors is at least two. The at least two infrared light sensors are respectively connected with signal input ends of the micro-processor system and form a probe group. A shading mechanism is arranged between the two infrared light sensors. The shading mechanism separates receiving zones for receiving light signals of the two infrared light sensors so that space zones which receive the light signals at different time exist in the receiving zones for receiving the light signals of the two infrared light sensors. A signal output end of the micro-processor system is connected with a control interface. The micro-processor system is connected with a controlled end of a carrier through a signal of the control interface. The probe group is used for being arranged on the carrier. The at least two infrared light sensors in the probe group receive the light signals.

Description

Laser remote-controlled receiving trap

Technical field

The utility model relates to electronic technology field, relates in particular to a kind of laser technology field.

Background technology

Because laser has the advantages such as directional lighting, energy density are large, laser beam emitting device and the laser remote-controlled receiving trap supporting with it have been used for a lot of fields.

In direction of motion is carried out the field of remote control of remote control, usually adopt Infrared remote controller that the running status of controlled article is controlled.Usually people adopt the Infrared remote controller with several buttons to carry out button operation, and the controlled end of controlled article is infrared receiving device, receive the infrared remote-controlled signal of Infrared remote controller emission, and process infrared remote-controlled signal, carry out corresponding operating.This control mode need to use a plurality of buttons on Infrared remote controller to operate, and an Infrared remote controller can only operate controlled article, has the problems such as limited of using.

The utility model content

Another purpose of the present utility model is, provides a kind of laser remote-controlled receiving trap, to solve the problems of the technologies described above.

The technical matters that the utility model solves can realize by the following technical solutions:

Laser remote-controlled receiving trap, comprise infrared optical sensor, microprocessor system, it is characterized in that, described infrared optical sensor comprises at least two, at least two described infrared optical sensors connect respectively the signal input part of described microprocessor system, and at least two described infrared optical sensors form one group of probe;

Be provided with a chopping mechanism between two infrared optical sensors, described chopping mechanism separates the receiving area of two described infrared optical sensor receiving optical signals, makes the receiving area existence of two described infrared optical sensor receiving optical signals not receive simultaneously the area of space of light signal;

The signal output part of described microprocessor system connects a control interface, and described microprocessor system is by the controlled end of described control interface signal connection carrier;

Described probe is used for being arranged on described carrier, at least two infrared optical sensor receiving optical signals in described probe, and will at least two induction informations send described microprocessor system to, at least two induction informations of described microprocessor system's processing, determine the receiving area, and produce corresponding control signal to described carrier.

Described laser remote-controlled receiving trap also comprises a laser pick-off housing, one group the probe at least two described infrared optical sensors be arranged side by side in described laser pick-off housing, be provided with described chopping mechanism between adjacent two described infrared optical sensors, and receiving end the place ahead printing opacity of described infrared optical sensor.

Described infrared optical sensor can adopt a kind of in photodiode, phototriode or infrared receiving terminal.Infrared receiving terminal is used comparatively general in existing infrared remote control receiving system, wherein integrated signal processing circuit.

Described laser remote-controlled receiving trap comprises at least two described probes of group.

Infrared optical sensor orientation at least two described probes of group is mutually vertical or be parallel to each other.

Described laser remote-controlled receiving trap comprises at least two described probes of group, the infrared optical sensor orientation of two groups of described probes is mutually vertical, the transversely arranged setting of infrared optical sensor in one group of described probe, the infrared optical sensor vertical array in the described probe of another group arranges.

Described carrier is mobile vehicle, and described carrier is done controlled motion on loading end, and described loading end comprises the face that can carry carrier, as liquid surface and solid surface; Described carrier is the object of doing controlled motion that is mounted with laser remote-controlled receiving trap, as is mounted with boats and ships, vehicle, electric wheelchair, toy car, loading-unloading vehicle, furniture, remote-controlled robot of laser remote-controlled receiving trap etc.

The orientation of the infrared optical sensor of horizontally set is parallel with described loading end; The orientation of the vertical infrared optical sensor that arranges is vertical with described loading end.The described probe of horizontally set determines direction information, and the vertical described probe that arranges is determined velocity information.

When the induction information that described microprocessor system transmits at the described probe to horizontally set is processed, come directions information according to the position, receiving area at light signal place; When the receiving area was positioned at described carrier dead ahead, progress signal was thought by described microprocessor system, and described microprocessor system sends to progress signal the controlled end of described carrier, controls described carrier and advances.

When described receiving area was positioned at a side in described carrier dead ahead, this side turn signal was thought by described microprocessor system, and described microprocessor system sends to this side turn signal the controlled end of described carrier, controls described carrier and turns to this side.

When the induction information that described microprocessor system transmits at the described probe to vertical setting is processed, determine velocity information according to the position of the receiving area at light signal place; The receiving area is far away apart from carrier, and bearer rate is faster, and described microprocessor system sends to velocity information the controlled end of described carrier, controls the speed of described carrier.

When any induction information is not received by the microprocessor system, Stop message is sent to the controlled end of described carrier, control described carrier brake or unpowered deceleration until stop motion.

Two described infrared optical sensor receiving areas in one group of described probe allow to exist the overlapping region, and each infrared optical sensor receiving area in two groups of described probes allows respectively to exist the overlapping region;

When two groups of described probe orientations are mutually vertical, at first described microprocessor system processes the induction information that one group of described probe sends, then the induction information that the described probe of another group is sent is processed, and realizes respectively direction information and velocity information being confirmed.

Described laser remote-controlled receiving trap comprises at least two described laser pick-off housings, is equipped with at least one group of described probe on each described laser pick-off housing, and described microprocessor system processes respectively the induction information that receives on each described laser pick-off housing.The utility model arranges a plurality of housings, and a plurality of probes can be placed on the diverse location of carrier, so that carrier can be comprehensive, perhaps needn't turn to can the execution action instruction.

Described carrier of the present utility model can be also the controlled article of signal, the controlled article of described signal are the static controlled article in position, such as being the article that adopt Infrared remote controller to control, such as televisor, refrigerator, infrared controlled curtain, infrared remote control window, infrared remote control toy etc.

Described laser remote-controlled receiving trap comprises at least two described probes of group, infrared optical sensor orientation in two groups of described probes is parallel to each other, described type processor system is processed at least four induction informations, and according to the time of reception sequencing of the light signal of different receiving areas, determine the trend of light signal, produce remote control actions.

For the utility model is applicable to the carrier that various employing telepilots are controlled, the utility model also comprises a remote controller module, the described remote controller module of described microprocessor system's control linkage; Described remote controller module adopts the study remote controller module, described study remote controller module comprises a signal processing module, an infrared emission head, a study with light activated element, one group of key groups, a memory module, and described signal processing module connects respectively described infrared emission head, described study with light activated element, described key groups and described memory module; The controlled end of described carrier is connected with an infrared remote control receiver module that allows to set up with described study remote controller module matching relationship.

The controlled end of described carrier receives the infrared remote-controlled signal of described infrared emission head emission, and described study is used for receiving the infrared remote-controlled signal of external remote emission with light activated element; At least a portion button of described key groups is related with described remote control actions;

Described study receives the infrared remote-controlled signal that needs study with light activated element, and the infrared remote-controlled signal that receives is converted into electric signal transmission to signal processing module, and be converted into data and store by memory module, when carrying out remote control actions, described signal processing module reads the data of storing in described memory module, and by described infrared emission head emission infrared remote-controlled signal, carry out remote control actions.

During study remote controller module concrete operations of the present utility model, select to enter the telepilot mode of learning by key groups, then by after key groups selection function information, press corresponding function key on telepilot, described telepilot is communicated by letter with light activated element with described study, described study receives the infrared remote-controlled signal of described telepilot emission with light activated element, and described infrared remote-controlled signal and described remote control actions is carried out related, is stored in the lump in memory module; Repeat to press the corresponding function key on key groups, telepilot, complete the telepilot mode of learning;

Described signal processing module is transmitted to the corresponding infrared remote-controlled signal of described remote control actions the controlled end of described carrier after determining remote control actions, described carrier is carried out remote control actions.

Described microprocessor system can adopt Single Chip Microcomputer (SCM) system, also can adopt the ARM system, described signal processing module can with described microprocessor system combination, realize the telepilot mode of learning by a described microprocessor system.Described signal processing module also can be separate with the microprocessor system, and described signal processing module connects described microprocessor system.

Described laser remote-controlled receiving trap also comprises a receiving trap monolithic case, and described microprocessor system, described probe are positioned at the whole housing of described receiving trap.So that structural entity.

Described laser pick-off housing is positioned at described receiving trap monolithic case.

The structure member of described laser remote-controlled receiving trap all is positioned at described receiving trap monolithic case.

Described receiving trap monolithic case simultaneously is provided with adhesive structure.Described adhesive structure can be the adhesive structures such as double faced adhesive tape, seamless glue, sucker.So that be adsorbed on carrier or be adsorbed near the object of carrier.

Laser remote control system, comprise laser beam emitting device, laser remote-controlled receiving trap, described laser beam emitting device is at least one, and described laser remote-controlled receiving trap is at least one, described laser beam emitting device emission infrared laser beam, described laser remote-controlled receiving trap receives infrared signal; At least one described laser remote-controlled receiving trap is separately positioned on carrier;

Described laser remote-controlled receiving trap detects the infrared signal of the infrared laser beam reflection of described laser beam emitting device emission, and obtain the receiving area, according to the position of receiving area, send corresponding infrared remote-controlled signal to described carrier, control the duty of carrier.

Described laser beam emitting device can be only one, and described laser remote-controlled receiving trap can be at least two, and at least two described laser remote-controlled receiving traps are separately positioned on different carriers; In order to control the purpose of a plurality of carriers by a laser beam emitting device.

Described laser beam emitting device can be arranged on different launching carriers, and described launching carrier can be that ring, mobile phone etc. are convenient to the article of taking and carrying.

Beneficial effect: owing to adopting technique scheme, the utility model adopts infrared signal to control the duty of carrier, same laser beam emitting device is controlled respectively the duty of a plurality of carriers, has avoided a telepilot can only control the problem of carrier.

Description of drawings

Fig. 1 is a kind of structural representation of the utility model laser beam emitting device;

Fig. 2 is the structural representation that the laser remote-controlled receiving trap of the utility model comprises one group of when probe;

Fig. 3 is a kind of structural representation that the laser remote-controlled receiving trap of the utility model comprises two groups of whens probe;

Fig. 4 is the another kind of structural representation that the laser remote-controlled receiving trap of the utility model comprises two groups of whens probe;

Schematic diagram when Fig. 5 is the use of the utility model remote controller module;

Fig. 6 is the structural representation of the utility model embodiment one;

Fig. 7 is the structural representation of the utility model embodiment two.

Embodiment

For technological means, creation characteristic that the utility model is realized, reach purpose with effect is easy to understand, below in conjunction with the further elaboration the utility model of concrete diagram.

With reference to Fig. 2, laser remote-controlled receiving trap, comprise infrared optical sensor 22, microprocessor system, infrared optical sensor 22 comprises at least two, at least two infrared optical sensors 2 connect respectively the signal input part of microprocessor system, and at least two infrared optical sensors 22 form one group of probe.Be provided with a chopping mechanism between two infrared optical sensors 22, chopping mechanism separates the receiving area of two infrared optical sensor 22 receiving optical signals, makes the receiving area existence of two infrared optical sensor 22 receiving optical signals not receive simultaneously the area of space of light signal.The signal output part of microprocessor system connects a control interface, and the microprocessor system is by the controlled end of control interface signal connection carrier.Probe is used for being arranged on carrier, at least two infrared optical sensors in probe are received light signals, and will at least two induction informations send the microprocessor system to, the microprocessor system processes at least two induction informations, determine the receiving area, and produce corresponding control signal to carrier.

Laser remote-controlled receiving trap also comprises a laser pick-off housing 21, one group the probe in two infrared optical sensors 22 be arranged side by side in laser pick-off housing 21, be provided with chopping mechanism between adjacent two infrared optical sensors 22, and receiving end the place ahead printing opacity of infrared optical sensor 22.Infrared optical sensor 22 can adopt a kind of in photodiode, phototriode or infrared receiving terminal.

Laser remote-controlled receiving trap comprises two groups of probes.Infrared optical sensor orientation in two groups of probes is mutually vertical or be parallel to each other.

With reference to Fig. 2, Fig. 4, laser remote-controlled receiving trap comprises two groups of probes, infrared optical sensor orientation in two groups of probes is mutually vertical, the transversely arranged setting of infrared optical sensor in one group of probe, and the infrared optical sensor vertical array in another group probe arranges.Carrier is mobile vehicle, and carrier is done controlled motion on loading end, and loading end comprises the face that can carry carrier, as liquid surface and solid surface.Carrier is the object of doing controlled motion that is mounted with laser remote-controlled receiving trap, as is mounted with boats and ships, vehicle, electric wheelchair, toy car, loading-unloading vehicle, furniture, remote-controlled robot of laser remote-controlled receiving trap etc.

The orientation of the infrared optical sensor of horizontally set is parallel with loading end.The orientation of the vertical infrared optical sensor that arranges is vertical with loading end.The probe of horizontally set determines direction information, and the vertical probe that arranges is determined velocity information.

When the microprocessor system processes at the induction information that the probe of horizontally set is transmitted, come directions information according to the position, receiving area at light signal place.When the receiving area was positioned at the carrier dead ahead, progress signal was thought by the microprocessor system, and the microprocessor system sends to progress signal the controlled end of carrier, controls carrier and advances.When the receiving area was positioned at a side in carrier dead ahead, this side turn signal was thought by the microprocessor system, and the microprocessor system sends to this side turn signal the controlled end of carrier, controls carrier and turns to this side.

As shown in Figure 2, two infrared optical sensors 22 side by side receive infrared signal, can determine the receiving area.The infrared optical sensor 22 that in figure, D1 can receive the infrared signal right side for the infrared optical sensor 22 in left side can't receive the receiving area of infrared signal; D2 is that the infrared optical sensor 22 on left side and right side all can be received the receiving area of infrared signal; D3 is that the infrared optical sensor 22 on right side can be received infrared signal and the infrared optical sensor 22 in left side can't receive the receiving area of infrared signal.

The infrared optical sensor 22 in left side receives infrared signal, and the right turn signal is thought by the microprocessor system; Left side and the infrared optical sensor 22 on right side are all received infrared signal, and progress signal is thought by the microprocessor system; The infrared optical sensor 22 on right side receives infrared signal, and left direction signal is thought by the microprocessor system.

When the microprocessor system processes at the induction information that the probe of vertical setting is transmitted, determine velocity information according to the position of the receiving area at light signal place.The receiving area is far away apart from carrier, and bearer rate is faster, and the microprocessor system sends to velocity information the controlled end of carrier, controls the speed of carrier.

With reference to Fig. 4, two infrared optical sensors 22 of vertically arranging receive infrared signal, can determine the receiving area.The infrared optical sensor 22 that in figure, S1 can receive the infrared signal top for the infrared optical sensor 22 of below can't receive the receiving area of infrared signal; S2 is that the infrared optical sensor 22 of above and below all can be received the receiving area of infrared signal; S3 can receive the infrared optical sensor 22 of infrared signal below for the infrared optical sensor 22 of top can't receive the receiving area of infrared signal.The speed of carrier can be thought and increases progressively to S3 receiving area relative velocity from S1.

When any induction information is not received by the microprocessor system, Stop message is sent to the controlled end of carrier, control carrier brake or unpowered deceleration until stop motion.

In above-mentioned design, two infrared optical sensor 22 receiving areas in one group of probe allow to exist the overlapping region, and each infrared optical sensor receiving area in two groups of probes allows respectively to exist the overlapping region.

When the orientation of two groups of probes was mutually vertical, at first the microprocessor system processed the induction information that one group of probe sends, and the induction information that then another group probe is sent is processed, and realizes respectively direction information and velocity information being confirmed.

Laser remote-controlled receiving trap comprises at least two laser pick-off housings, is equipped with at least one group of probe on each laser pick-off housing, and the microprocessor system processes respectively the induction information that receives on each laser pick-off housing.The utility model arranges a plurality of housings, and a plurality of probes can be placed on the diverse location of carrier, so that carrier can be comprehensive, perhaps needn't turn to can the execution action instruction.

Carrier of the present utility model can be also the controlled article of signal, such as being the article that adopt Infrared remote controller to control, such as televisor, refrigerator, infrared controlled curtain, infrared remote control window, infrared remote control toy etc.

With reference to Fig. 3, laser remote-controlled receiving trap comprises two groups of probes, two groups the probe in infrared optical sensor 22 orientations be parallel to each other, the type processor system is processed at least four induction informations, and according to the time of reception sequencing of the light signal of different receiving areas, determine the trend of light signal, produce remote control actions.The infrared signal in four zones of the place ahead L1, L2, L3, L4 detects in four infrared optical sensors 22 branches in two groups of probes.In Fig. 3, be two groups of side views of being parallel to each other of infrared optical sensor 22 orientations in probe, therefore only show L1, L2 two zones.Whether the microprocessor system can detect infrared signal according to four infrared optical sensors 22, and the time order and function order of light signal detected, determines the trend of laser beam.The designs of two groups of probes, can determine left side, right side, top, below, from left to right, turn left from the right side, from the bottom up, from top to bottom, from the lower-left toward the upper right, from the bottom right toward the upper left, from the upper right toward the lower-left, the inferior several azimuth informations of turning right from the upper left definite.

Certainly laser remote-controlled receiving trap 2 of the present utility model, do not limit above-mentioned two groups of probes, and many group probes can be set as required, and many group probes can be determined more multi-faceted information.

With reference to Fig. 5, for the utility model is applicable to the carrier that various employing telepilots are controlled, the utility model also comprises a remote controller module, microprocessor system control linkage remote controller module.Remote controller module adopts the study remote controller module, and remote controller module comprises that a signal processing module, an infrared emission head 31, a study are with light activated element 32, one group of key groups 33, a memory module.Signal processing module connects respectively infrared emission head 31, study light activated element 32, key groups 33 and memory module.The controlled end of carrier receives the infrared remote-controlled signal of infrared emission head 31 emissions, and study is used for receiving the infrared remote-controlled signal of external remote emission with light activated element 32.At least a portion button of key groups 33 is related with remote control actions.Study receives with light activated element 32 infrared remote-controlled signal that needs study, and the infrared remote-controlled signal that receives is converted into electric signal transmission to signal processing module, and be converted into data and store by memory module, when carrying out remote control actions, signal processing module reads the data of storing in memory module, and launch infrared remote-controlled signal by infrared emission head, carry out remote control actions.

During study remote controller module concrete operations of the present utility model, select to enter the telepilot mode of learning by key groups 33, after key groups 33 selection function information, press corresponding function key on telepilot 4, telepilot 4 is communicated by letter with light activated element 32 with study, study receives the infrared remote-controlled signal of telepilots 4 emissions with light activated element 32, and infrared remote-controlled signal and remote control actions is carried out related, is stored in the lump in memory module; Repeat to press the corresponding function key on key groups 33, telepilot 4, complete the telepilot mode of learning.Signal processing module is transmitted to the corresponding infrared remote-controlled signal of remote control actions the controlled end of carrier after determining remote control actions, carrier is carried out remote control actions.

Key groups 33 of the present utility model can comprise mode of learning button, a plurality of function information button, the function information button such as comprise that volume increases, volume reduces, program advances, program retreats, switch program, the button such as quiet, menu.

Be increased to example with volume, carrier is televisor, and the use step of study remote controller module can be in the following way:

1) press mode of learning button on infrared receiving device, enter the telepilot mode of learning;

The volume of 2) pressing on infrared receiving device increases button, and telepilot 4 is towards study light activated element 32, and the volume of pressing on telepilot 4 increases button.

3) signal processing module is processed infrared remote-controlled signal, the trend of light signal from the bottom up in related infrared remote-controlled signal and Fig. 3.

4) the microprocessor system connects signal processing module, and microprocessor system validation light signal trend sends corresponding infrared remote-controlled signal to the controlled end of televisor, the increase of control tv volume for from the bottom up the time.

The microprocessor system can adopt Single Chip Microcomputer (SCM) system, also can adopt the ARM system.Signal processing module can with the microprocessor system combination, realize telepilot 4 modes of learning by a microprocessor system.Signal processing module also can be separate with the microprocessor system, and signal processing module connects the microprocessor system.

Laser remote-controlled receiving trap 2 also comprises a receiving trap monolithic case, and microprocessor system, probe are positioned at the whole housing of receiving trap.The laser pick-off housing also can be positioned at the receiving trap monolithic case, and the structure member of even laser remote-controlled receiving trap 2 all is positioned at the receiving trap monolithic case.So that structural entity.

The receiving trap monolithic case simultaneously is provided with adhesive structure.Adhesive structure can be the adhesive structures such as double faced adhesive tape, seamless glue, sucker.So that be adsorbed on carrier or be adsorbed near the object of carrier.

With reference to Fig. 6, Fig. 1, laser remote control system comprises laser beam emitting device 1, laser remote-controlled receiving trap 2, laser beam emitting device 1 is at least one, laser remote-controlled receiving trap 2 is at least one, the infrared laser beam of laser beam emitting device 1 emission, and laser remote-controlled receiving trap 2 receives infrared signal.At least one laser remote-controlled receiving trap 2 is separately positioned on carrier 5.The infrared signal of the infrared laser beam reflection of laser remote-controlled receiving trap 2 detection laser emitter emissions, and obtain the receiving area, according to the position of receiving area, send corresponding infrared remote-controlled signal to carrier 5, control the duty of carrier.

Laser beam emitting device 1 can be only one, and laser remote-controlled receiving trap 2 can be at least two, and at least two laser remote-controlled receiving traps 2 are separately positioned on different carrier 5.In order to control the purpose of a plurality of carriers 5 by a laser beam emitting device 1.

Laser beam emitting device 1 can be arranged on different launching carriers, and launching carrier can be that ring, mobile phone etc. are convenient to the article of taking and carrying.

Embodiment one: with reference to Fig. 6, carrier 5 is toy car, and laser beam emitting device 1 is arranged on ring, and laser remote-controlled receiving trap 2 is two, is separately positioned on the front-end and back-end of toy car, so that remote-controlled toy vehicle moves forward and backward.Laser remote-controlled receiving trap can be carried out signal with the control end of toy car is connected.

Laser beam emitting device 1 emission infrared laser beam is controlled working direction, left-hand rotation, the right-hand rotation of toy car.As shown in Figure 6, the infrared laser beam of laser beam emitting device 1 emission is positioned at the top, after the microprocessor system processes infrared signal, confirms as right turn signal, controls toy car and turns right.

Embodiment two: with reference to Fig. 7, carrier 5 is the televisor of Infrared remote controller remote control, and laser beam emitting device 1 Laser emission housing is barred body 11, and laser remote-controlled receiving trap 2 is one, a laser remote-controlled receiving trap 2 comprises four groups of probes, and four groups of probes are separately positioned on the bight of televisor.

The telepilot of televisor is adopted study remote controller module of the present utility model, the infrared remote-controlled signal of telepilot is read one by one.

Laser beam emitting device 1 emission infrared laser beam, as operating platform, the microprocessor system controls the state of televisor according to the trend of infrared signal with the screen of televisor.

Above demonstration and described ultimate principle of the present utility model and principal character and advantage of the present utility model.The technician of the industry should understand; the utility model is not restricted to the described embodiments; that describes in above-described embodiment and instructions just illustrates principle of the present utility model; under the prerequisite that does not break away from the utility model spirit and scope; the utility model also has various changes and modifications, and these changes and improvements all fall in claimed the utility model scope.The claimed scope of the utility model is defined by appending claims and equivalent thereof.

Claims (11)

1. laser remote-controlled receiving trap, comprise infrared optical sensor, microprocessor system, it is characterized in that, described infrared optical sensor comprises at least two, at least two described infrared optical sensors connect respectively the signal input part of described microprocessor system, and at least two described infrared optical sensors form one group of probe;

Be provided with a chopping mechanism between two infrared optical sensors, described chopping mechanism separates the receiving area of two described infrared optical sensor receiving optical signals, makes the receiving area existence of two described infrared optical sensor receiving optical signals not receive simultaneously the area of space of light signal;

The signal output part of described microprocessor system connects a control interface, and described microprocessor system is by the controlled end of described control interface signal connection carrier;

Described probe is used for being arranged on described carrier, at least two infrared optical sensor receiving optical signals in described probe.

2. laser remote-controlled receiving trap according to claim 1, it is characterized in that, also comprise a laser pick-off housing, one group the probe at least two described infrared optical sensors be arranged side by side in described laser pick-off housing, be provided with described chopping mechanism between adjacent two described infrared optical sensors, and receiving end the place ahead printing opacity of described infrared optical sensor.

3. laser remote-controlled receiving trap according to claim 1, is characterized in that, described laser remote-controlled receiving trap comprises at least two described probes of group.

4. laser remote-controlled receiving trap according to claim 1, is characterized in that, described laser remote-controlled receiving trap comprises at least two described probes of group, and the infrared optical sensor orientation in two groups of described probes is parallel to each other.

5. laser remote-controlled receiving trap according to claim 1, it is characterized in that, described laser remote-controlled receiving trap comprises at least two described probes of group, the infrared optical sensor orientation of two groups of described probes is mutually vertical, the transversely arranged setting of infrared optical sensor in one group of described probe, the infrared optical sensor vertical array in the described probe of another group arranges.

6. laser remote-controlled receiving trap according to claim 1, is characterized in that, there is the overlapping region in two described infrared optical sensor receiving areas in one group of described probe.

7. laser remote-controlled receiving trap according to claim 3, is characterized in that, there is respectively the overlapping region in each infrared optical sensor receiving area in two groups of described probes.

8. the described laser remote-controlled receiving trap of any one according to claim 1 to 7, is characterized in that, described carrier is mobile vehicle, and described carrier is on loading end, and described carrier is the object of doing controlled motion that is mounted with laser remote-controlled receiving trap.

9. laser remote-controlled receiving trap according to claim 8, is characterized in that, the orientation of the infrared optical sensor of horizontally set is parallel with described loading end; The orientation of the vertical infrared optical sensor that arranges is vertical with described loading end.

10. the described laser remote-controlled receiving trap of any one according to claim 1 to 7, it is characterized in that, described laser remote-controlled receiving trap also comprises a receiving trap monolithic case, described microprocessor system, described probe are positioned at the whole housing of described receiving trap, and described receiving trap monolithic case simultaneously is provided with adhesive structure.

11. according to claim 1 to 7, the described laser remote-controlled receiving trap of any one, is characterized in that, comprises a remote controller module, the described remote controller module of described microprocessor system's control linkage; Described remote controller module adopts the study remote controller module, described study remote controller module comprises a signal processing module, an infrared emission head, a study with light activated element, one group of key groups, a memory module, and described signal processing module connects respectively described infrared emission head, described study with light activated element, described key groups and described memory module; The controlled end of described carrier is connected with an infrared remote control receiver module that allows to set up with described study remote controller module matching relationship.

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