CN203416263U - Infrared photoconduction remote control system - Google Patents

Abstract

An infrared photoconduction remote control system comprises a guiding terminal and a mobile terminal. The infrared photoconduction remote control system is characterized in that on the movement carrier of the mobile terminal, a plurality of infrared ray transmitting tubes comprise an array to emit multipath infrared ray signals for direction detection in sequence in a time-sharing manner, the guiding terminal is provided with an infrared receiver with high sensitivity, the infrared receiver receives and detects parameters of all infrared ray signals in series, azimuth information is obtained after data calculation to form control instruction signals, the control instruction signals are emitted to the mobile terminal through a remote control emitter to control the movement carrier to track and guide, the guiding position and direction are indicated by the guiding terminal through light spots guided by visible light , synchronous signals are transmitted between the mobile terminal and the guiding terminal, and the synchronous corresponding relation of emission and reception signals is maintained.

Description

Infrared ray optical direction remote control system

Technical field

The present invention is a kind of infrared ray photoelectric orientation detection and remote tracking guidance system, adopt multichannel timesharing transmitting infrared ray bearing signal, single channel serial received to detect and teleguide technology, relate to infrared ray, light-emitting diode, photoelectric sensing, photometry, orientation detection, guiding tracking, teleguide, time division multiplexing, the field such as synchronous.

Background technology

In fields such as radar, navigation, sonars, utilize the orientation of the directivity measurement target of antenna, detection range is far away, but antenna size is very large.

Photoelectric sensor has advantages of that volume is little, uses a plurality of photoelectric cells to form sensor array, by the light distribution in measurement space, also can carry out orientation detection, is applied to the toy robot of light source tracking and the model car tracking, light sensation guiding etc.

But the working method that these systems adopt a plurality of photelectric receiver multichannels to detect, there is discreteness and otherness in the characterisitic parameter of the photoelectric cell of each photelectric receiver, amplifier and other parts, between each road, be difficult to keep consistency, very large on the impact of measurement result, need to carry out complicated correction, limit the raising of measuring accuracy and distance.

Summary of the invention

The present invention adopts the technology such as multichannel timesharing transmitting infrared ray bearing signal, the detection of single channel serial received and teleguide, has designed a kind of infrared ray optical direction remote control system.

As shown in Figure 1: this system is comprised of guide end and mobile terminal two large divisions.Motion carrier 11(such as the model car of mobile terminal, toy robot, toy for animal etc.) upper, by a plurality of infrared emission tubes 1, form array, timesharing is the multiplex infrared signal 3 of launch azimuth detection use successively; Guide end is installed a highly sensitive infrared receiver 2, serial received also detects the parameter of each road infrared signal 3, after data computing, obtain the information such as azimuth, formation control command signal, by remote control transmitter 7, send to mobile terminal again, controlled motion carrier 11 is followed the tracks of, is guided.

Guiding hot spot 16 indication guiding position and the directions of visible ray for guide end.Between mobile terminal and guide end, transmit synchronizing signal, keep transmitting and receiving the synchronous corresponding relation of Ge road signal.

This system is only used an infrared receiver, serial received infrared emission tube array time-sharing transmitting Ge road orientation detection signal, while having avoided adopting a plurality of photelectric receiver, the impact on measurement result of the discreteness of part characteristic parameter and otherness, has improved detection accuracy.And can adopt the receiver of high-amplification-factor, and improve detection sensitivity and detect distance, realize remote input (can reach the distance order of magnitude of common infra-red remote control).

This system has the distance of detection, precision is high, volume is little, simple to operate, low cost and other advantages.

Accompanying drawing explanation

Fig. 1 is system schematic;

Fig. 2 is that system forms structure chart;

Fig. 3 is the infrared emitting figure of infrared emission tube;

Fig. 4 is the octagon array of figure that 8 infrared emission tubes are arranged in, and comprises the cross and the X-shaped array that by 4 transmitting tubes, are arranged in respectively;

Fig. 5 (a) is the V-arrangement array of figure that 2 infrared emission tubes are arranged in;

Fig. 5 (b) is for having 3 array of figure that infrared emission tube is arranged in of the angle of pitch;

Fig. 6 is the regular hexagon array of figure that 6 infrared emission tubes are arranged in;

Fig. 7 is the schematic diagram of infrared synchronous signals transmitting tube;

Fig. 8 is the frame assumption diagram of the pulse signal of infrared emission tube array time-sharing transmitting;

Fig. 9 is the frame assumption diagram of infrared receiver output Ge road pulse signal;

Figure 10 is carrier modulation and the power driving circuit block diagram of infrared emission tube;

Figure 11 is the carrier waveform figure of infrared emission tube;

Figure 12 is the circuit structure block diagram of multiple signals synchronous distributor and separator;

Figure 13 is the composition structure chart of infrared receiver;

Figure 14 (a) is that the luminosity parameter space of transmitting tube array distributes calculating with scheming;

Figure 14 (b) is the array orientation angle computing function curve chart of 2 transmitting tubes;

Figure 14 (c) is the array orientation angle computing function curve chart of 3 transmitting tubes;

Figure 15 is signal processing flow figure;

Figure 16 is white light and color LED array and the structure chart of guiding hot spot;

Figure 17 is guide end global design figure;

Figure 18 is the signal frame format chart of the symmetrical scanning method of multi-pulse repetition period;

Figure 19 is the global design figure of the centralized installation in mobile terminal.

Embodiment

Fig. 2 is that system forms structure chart: this system is comprised of guide end and mobile terminal two large divisions.Mobile terminal comprises the parts such as infrared emission tube array 12, pulse signal generator 19, multiple signals synchronous distributor 123, carrier modulation 17 and power drive 18 circuit, receiver of remote-control sytem 6, motion carrier 11; The composition of guide end comprises the parts such as the data computings 9 such as infrared receiver 2, multiple signals sync separator 123, pulse parameter measure 13, azimuth, control signal generation 9, remote control transmitter 7, white light and color LED array 160.Wherein the data computing such as azimuth and control signal produce function 9 and also can be configured in mobile terminal.

Mobile terminal forms infrared emitting array 12 by a plurality of infrared emission tubes 1; Pulse signal generator 19 produces the pulse train with certain pulse duration and interval; Under the effect of synchronizing signal 121, by multiple signals synchronous distributor 123, each pulse cycle in pulse train is assigned to the drive circuit 18 of each transmitting tube, through carrier modulation 17, timesharing is launched successively.

Each road infrared signal, through straightline propagation or by the body surfaces such as ground, wall (diffuse surface 5) diffuse reflection, forms the infrared ray light intensity distribution that orientation detection is used in space.

The working method of guide end is divided into guide mode and guide mode.The direct light signal of guide mode middle infrared (Mid-IR) receiver 2 direct receiving infrared-ray emission arrays, itself is guiding point infrared receiver; The optical axis of guide mode middle infrared (Mid-IR) receiver 2 points to a location point on diffuse surface 5, receives the signal that diffuses at this some place, and this point is guiding point.

Each road infrared pulse signal of infrared receiver 2 serial received of guide end, after amplifying, a pulse parameter of output (for example width or amplitude) for example, along with the pulse train of luminosity parameter (luminous intensity, illumination or the brightness) variation of infrared signal; Under the effect of synchronizing signal 121, according to the order identical with transmitting terminal, by multiple signals sync separator 123Jiang Ge road pulse signal, from pulse train, separated, carry out respectively the measurement 13 of pulse parameter.

Then Dui Ge road signal value carries out data computing, obtains the information such as azimuth 9, produces control command signal 9, and the actuating mechanism on controlled motion carrier 11 is carried out action accordingly, to guiding point, moves, and realizes guiding, follows the tracks of and other control function.

Guide end is installed remote control transmitter 7, and receiver of remote-control sytem 6 is installed in mobile terminal, and various control commands and data are sent to mobile terminal from guide end.

White light and color LED array 160 transmitting visible light beams for guide end, form the guiding hot spot 16 centered by guiding point, indication guiding position and direction.

Between mobile terminal and guide end, transmit synchronizing signal 121, for determining the sequential position of each pulse signal, keep transmitting and receiving the synchronous corresponding relation of Ge road signal.

Fig. 3 is the infrared emitting figure of infrared emission tube.Infrared emission tube (Infrared LED) the 1st, the ultrared light-emitting diode of a kind of transmitting, transmitting power is directly proportional to forward operating current, the infrared ray 31 of transmitting has directivity, straightline propagation the same as visible ray, projects the body surfaces (diffuse surface 5) such as ground, wall diffuse reflection 32 can occur.

Compare with the laser beam of LASER Discharge Tube transmitting, the infrared light beam of infrared emission tube transmitting has the larger angle of divergence, but fail safe is good, reliable operation, and cost is low.Compare with radio wave, sonar array, infrared emission tube has the advantages such as volume is little, easy for installation, group battle array is flexible, driving circuits is simple.Compare with the LED light-emitting diode of transmitting visible ray, the anti-interference of stray light ability of infrared ray of infrared emission tube transmitting is strong.

A plurality of infrared emission tubes at spatial arrangement, form infrared emission tube array according to certain geometry.For example: 2 transmitting tubes are arranged forming V-shape (Fig. 5 (a)), 3 transmitting tubes are arranged in Y shape or △ shape, 4 transmitting tubes are arranged in cross (A in Fig. 4, C, E, G) or X-shaped (B in Fig. 4, D, F, H), and 6 transmitting tubes are arranged in hexagon (Fig. 6), 8 transmitting tubes are arranged in octagon (Fig. 4) etc.In addition also have the formations such as circular, spherical, conical.

Shape (half intensity radiation angle for example at a certain angle between the optical axis of each transmitting tube θ _1/2 ), phase pair array basic point (array center), orienting line or diffuse surface have specific azimuth and the angle of pitch (referring to Fig. 5 (a), (b)).The infrared ray of transmitting, space crossed overlapping, forms the spatial light intensity distribution that orientation detection is used.

In infrared emitting array, for improving transmitting operating distance, can dipped beam (short range) and distance light (long-range) transmitting tube be set layering.For improving orientation angles resolution, special-purpose auxiliary transmitting tube can be set.Also be useful on the synchronizing signal transmitting tube of transmitting infrared ray lock-out pulse etc.

When detection distance is greater than the physical dimension of transmitting tube and emission array, transmitting tube can be considered as being positioned at the point-source of light of array center, the luminosity parameter of computing array (for example luminous intensity, illumination or brightness) distributes.

As shown in Figure 14 (a): take emission array central rotation symmetry axis as zaxle is set up coordinate system, and test point or diffuse surface are positioned at xyplane, xaxle is azimuth baseline; Array center is positioned at zon axle o'point, xysubpoint in plane is the origin of coordinates o, be highly h; The optical axis of transmitting tube A with xaxle meets at o _a point (azimuth is 0 °), with xyplane included angle (angle of pitch) is α; Test point (guiding point) qbe positioned at xyplan radius is rcircle on, azimuth is φ, light o'Qwith xyplane included angle (angle of pitch) is γ, with transmitting tube optical axis o'O _a angle be θ, o'arrive qdistance is l.

By each point coordinates

　　　　　

With trigonometric function relational expression:

　　　　　

Calculate:

　　　　　

(1)

Transmitting tube light distribution approximate representation is:

　　　　　

Wherein i ₀ for the luminous intensity of optical axis direction,

θfor the deflection (with the angle of optical axis) of emission of light,

, θ _1/2 for half intensity radiation angle;

(1) formula substitution is calculated qthe light intensity at some place i (φ)for:

　　　　　

(2)

Illumination computing formula on reflecting surface is:

　　　　　

(2) formula substitution is calculated qthe illumination at some place e (φ)for:

　　　　　

(3)

The brightness of the diffuse reflection of ideal conditions in all directions is identical, is directly proportional to the illumination of incident light.Brightness calculation formula on diffuse surface is:

　　　　　

Wherein σfor diffuse reflectance;

(3) formula substitution is calculated qthe brightness at some place l (φ)for:

　　　　　 (4)

When transmitting tube level is installed, optical axis is positioned at same plane, the angle of pitch αbe 0 °, formula (1) is reduced to:

　　　　　

qthe light intensity at some place i (φ)for:

　　　　　

(5)

According to rotational symmetry, when the azimuth of transmitting tube in emission array is φ ₀ time, only need in above-mentioned each luminosity Parameters Calculation formula, use ( φ-φ ₀ ) replacement φ.

All or part of transmitting tube in infrared emission tube array as required, detects the infrared pulse signal of use according to certain order and combination timesharing launch azimuth.For example, when search pattern, all transmitting tube is launched successively, realizes omnidirectional's scanning.When tracing mode, only have the part transmitting tube timesharing transmitting for following the tracks of, to improve transmitting repetition rate, increase certainty of measurement.Can also allow the transmitting tubes such as short range, long-range, auxiliary angle measurement launch respectively.

Firing order has ortho position order, phase contraposition order, ortho position built-up sequence etc.The regular hexagon emission array that 6 transmitting tubes shown in Fig. 6 of take form is example: the firing order of each transmitting tube can be according to them the order of the ortho position in emission array A-B-C-D-E-F, or adopt relative position order A-D-B-E-C-F.In order to improve transmitting range, the combination of employing ortho position A+B, B+C ..., F+A etc.

Pulse generator produces the pulse train with certain pulse duration and pulse spacing, under the effect of synchronizing signal, by multiple signals synchronous distributor, each pulse cycle in pulse train is assigned to each infrared emission tube, successively transmitting.

Fig. 8 is the frame assumption diagram of the pulse signal of timesharing transmitting.Synchronization pulse 121 and a plurality of orientation detection pulse 86 form a frame.Synchronization pulse 121, for the beginning of mark one frame, is adjusted synchronised clock 80, determines sequential position (the beat T of each pulse in frame ₁, T ₂, T ₃deng).

Distribute to successively each transmitted pulse of each transmitting tube, comprise pulse A801, pulse B802, pulse C803 etc., form a transmitting circulation, its time span is called a transmitting cycle 87.Every frame pulse sequence can comprise one or more groups transmitting circulation.Pulse duration, pulse spacing, frame length 88, frame period 89 should meet the semaphore request of infrared receiver.The transmitting cycle should be not long, because the motion of motion carrier may cause that the basic point of emission array and the position of baseline move during this period, causes the error of azimuthal measurement.

Can also adopt self-synchronizing method, not send special-purpose synchronizing signal, but adopt the pulse signal of particular order, position or coding to form pulse train.For example, for the regular hexagon emission array in Fig. 6, adopt the symmetrical scanning method of multi-pulse repetition period, as shown in figure 18: a frame signal comprises two groups of transmitting circulations 181 and 182, respectively by adopting the pulse A-B-C-D-E-F of clockwise scanning sequence and adopting the pulse F-E-D-C-B-A of counterclockwise scanning sequence to form; The pulse repetition period 180 of each road pulse signal is different: A ... A, B ... B, C ... C ..., F ... the repetition period of F is respectively 12,10,8 ..., 2 pulse periods, receiving terminal is determined the corresponding relation of each road pulse by detecting the repetition period of pulse signal.

Multiple signals synchronous distributor, under the effect of synchronizing signal, is assigned to each infrared emission tube by each pulse cycle in frame pulse sequence.

Shown in Figure 12 is a kind of multiple signals synchronous distributor 123 consisting of digital and analog circuit.Clock generator 120 produces synchronised clock under the effect of synchronizing signal 121, is input to the pulse beat generator 122 consisting of counter etc., produces successively T ₁, T ₂..., T ₆etc. sequential beat, control corresponding analog switch 127, each pulse in pulse train 126 is extracted according to beat, form respectively A road pulse 1201, B road pulse 1202 ..., F road pulse 1206 etc.

Multiple signals synchronous distributor also can be realized by program software.

Figure 10 is carrier modulation and the power driving circuit block diagram of infrared emission tube, the carrier waveform figure that Figure 11 is infrared emission tube.Infrared emission tube 1 is worked in the mode of impulse ejection, and infrared signal 106 is modulated on carrier pulse and is launched by switching circuit 107, to increase transmitting range, reduce power consumption, to improve antijamming capability.

The infrared emitting power of infrared emission tube and forward operating current i _f 111 are directly proportional, and for keeping working stability, avoid being subject to the impact of temperature, mains voltage variations etc., can use constant-current source 105 to drive.The output driving current of constant-current source regulates by modes such as external variable resistors 104.

Carrier pulse carrier oscillator 103 being produced according to power control signal 101 grades carries out PWM(pulse duration) modulate 102, change width 110 and the duty ratio of carrier pulse, can change the size of the average operating current of infrared emission tube, regulate the average transmit power of infrared emission tube.

In infrared emitting array there is discreteness and otherness in the characterisitic parameter of different infrared emission tubes, but only need regulate the size of forward operating current just can carry out at an easy rate Concordance.For example regulate respectively each to drive the output current of constant-current source, just can adjust the transmitting power of infrared emission tube, keep the emissive porwer of each road infrared signal identical.

Regulate the forward operating current 111 of infrared emission tube or the width 110 of carrier pulse, can regulate the transmitting power of infrared emitting array, for the automatic control of transmitting power etc.

The infrared receiver serial received infrared emission tube array time-sharing of guide end is launched Ge road infrared signal, realizes opto-electronic conversion, amplification, the signal output function of infrared signal.

Figure 13 is the composition structure chart of infrared receiver, by optical system 130, photoelectric cell 131, amplifier 132, AGC(automatic gain, is controlled) 133, band pass filter 134, signal demodulation 135, export 136 etc. and partly form.

The optical system of infrared receiver detects direct light or the luminosity parameter (luminous intensity, illumination or brightness) that diffuses, according to the different requirements of measured light intensity, illumination or brightness, design with reference to photometer, illuminance meter, luminance meter etc., assembly comprises filter, lens, diaphragm, speculum etc., and infrared receiver deflection should be along optical axis Rotational Symmetry.

The circuit of infrared receiver can adopt application-specific integrated circuit (ASIC), universal integrated circuit or discrete device to form.Should adopt the amplifier of highly sensitive photoelectric cell (for example PIN photodiode) and high-gain, to detect faint infrared signal, improve receiving range.Output signal strength (for example pulse duration or amplitude) for example, has good linear relationship with the luminosity parameter (luminous intensity, illumination or brightness) of input infrared signal.

The integrated infrared receiving terminal that household remote is used (Infrared Receiver Modules, infrared remote receiver module) whole infrared receiving circuits are packaged together, the round lens of being furnished with converging action on shell, when infrared ray signal strength signal intensity hour, pulse duration and the infrared light intensity of output have (logarithm) linear relationship preferably, also have highly sensitive (receiving range can reach several meters to tens of rice), and volume is little, the advantages such as strong interference immunity are a kind of optional devices.

Because only use an infrared receiver, serial received timesharing transmitting Ge road infrared signal, all signals all pass through same optical system and photo-electric conversion element and receive, by single pass amplifier, amplified and pulse signal forms processing of circuit, while having avoided adopting a plurality of photelectric receiver, the impact on measurement result of the discreteness of part characteristic parameter and otherness, has improved detection accuracy.And can adopt the receiver of high-amplification-factor, and improve detection sensitivity and detect distance, realize remote input (can reach the distance order of magnitude of common infra-red remote control).

Fig. 9 is the frame assumption diagram of infrared receiver output Ge road pulse signal.The pulse train that infrared receiver output You Ge road infrared signal forms, under the effect of synchronizing signal 121, according to the order identical with transmitting terminal, according to the beat position of synchronised clock 90, by multiple signals sync separator Jiang Ge road pulse signal (pulse A901, pulse B902, pulse C903 etc.), from frame pulse sequence 96, separated, carry out respectively the measurement of pulse parameter.

The multiple signals sync separator of guide end is synchronoused working with the multiple signals synchronous distributor of mobile terminal, can adopt device or the program of same composition structure, referring to Figure 12.

Figure 15 is signal processing flow figure.Signal processing flow comprises input, parameter measurement, data processing, numerical computations, control signal generation etc., treatment step is: initialization 1501, parameter (width or amplitude) to the pulse of infrared receiver output measures 1502, identifies after lock-out pulse 1503 frame timing device, beat generator etc. 1504 are set.According to the validity 1505 of the beat position detection pulse of pulse, effective orientation detection pulse 1506 is carried out to separated in synchronization, carry out respectively parameter value cumulative 1507.After one frame end 1508, frame period in the time to frame in or the data processing 1509 such as the calculating such as the multiframe Ge road pulse value of averaging, maximum, minimum value, deviation, variance and smothing filtering, the information 1510 such as computer azimuth angle, then sends control signal 1511 again.

Signal is processed can use the realizations such as analog circuit, digital circuit, programmable logic device, microcontroller (single-chip microcomputer).

For pulse parameter measure, when adopting analog circuit, can take low-pass filtering, direct current mean value is measured, adopt operational amplifier, analog divider, digital circuit etc. to carry out data processing.While adopting single-chip microcomputer with digital timing mode ranging pulse width, use A/D conversion regime ranging pulse amplitude, and in frame or the measurement result of multiframe pulse carry out the data processings such as digital filtering.

According to different detection models and algorithm ，Dui Ge road signal value carry out numeric ratio, the calculating such as logical operation, arithmetical operation, functional operation, obtain the azimuth information of centrifugal pump or successive value.

The summation of each road signal value or mean value can be used as the reference of signal strength signal intensity, relative distance.

Control signal comprises the homing guidance signal of motion carrier, formation switching signal of infrared emitting array, transmission power adjustment signal etc.

According to information such as the type of drive of motion carrier, homing guidance algorithm and azimuth, distances, produce corresponding actuating mechanism control signal.Such as producing for model car, advance, retreat, turn left, the direction control signal such as right-hand rotation and speed stage, angle of turn, acceleration equal proportion control signal.

The needs that detect according to guide end bearing signal, the formation control signal of generation infrared emitting array, allows emission array change between the working methods such as search pattern, tracing mode, short range, long-range, auxiliary angle measurement, realizes effective orientation detection.

According to parameter generating transmission power adjustment signals such as the mean value of each road signal, maximum, minimum values, change the forward operating current of infrared emission tube or the width of carrier pulse, the transmitting power that regulates infrared emitting array, guarantees that infrared receiver is operated in the range of linearity.

Every signal processing function in signal processing flow can be realized in guide end design, also azimuth can be calculated, the signal processing function such as control command generation is placed on mobile terminal and realizes.

Calculating for azimuth centrifugal pump, the regular hexagon array that 6 transmitting tubes shown in Fig. 6 of take form is example: based on each transmitting tube symmetry that arrange in position in emission array, utilize the optical axis 61 of transmitting tube and the 62 pairs of area of space of equisignal line (face) in array pattern to divide.

Use numeric ratio, logical calculation device or program, Dui Ge road signal value carries out numerical values recited comparison, comprise the comparison of the position transmitting tube signal values such as phase ortho position, phase contraposition, gap digit, compared result is carried out logical combination computing, determine quadrant, the region at maximum value signal place and segment, according to the azimuth coverage obtaining, producing corresponding control signal.

The azimuth coverage that the regular hexagon array that 6 transmitting tubes shown in Fig. 6 are formed carries out divides and control signal is as shown in table 1 accordingly:

The azimuth coverage of table 1 regular hexagon array is divided and control signal

。

Use evolution and, poor, than (removing), take advantage of, calculation element or the program such as trigonometric function, antitrigonometric function, successive value calculating is carried out in the azimuth of guiding point.The measured value that is input as each road infrared signal of calculation element or program (for example luminous intensity, illumination or brightness are directly proportional to the luminosity parameter at guiding point place), be output as the azimuth of the relative emission array of guiding point, computing formula for example, is selected according to the quantity of transmitting tube and the geometric parameter (azimuth and the angle of pitch of each transmitting tube in emission array) of transmitting formation.

The array (referring to Fig. 5 (b)) that is α for the angle of pitch of the optical axis of transmitting tube, establishes 3 transmitting tube A, B, the azimuth of C in emission array is respectively -Δ φ, 0, Δ φ, the brightness value that guiding point place detects is respectively e _a , e _b , e _c (function curve diagram is calculated at the azimuth with reference to Figure 14 (c)).

According to formula (3), obtain:

　　　　　

Three formula both sides are done respectively minferior extracting operation obtains:

　　　　　

Note

　　　　　

　　　　　

Utilize trigonometric function formula to carry out and, poor, compare, multiplication obtains:

　　　　　

Negate trigonometric function obtains:

　　　　　

So the computing formula of the azimuth φ of guiding point is:

　　　　　

(6)

If the light intensity value that guiding point place detects is respectively i _a , i _b , i _c , according to formula (2), calculate azimuth φfor:

　　　　　

(7)

If the brightness value that guiding point place detects is respectively l _a , l _b , l _c , according to formula (4), calculate azimuth φfor:

　　　　　

(8)

If fthe measured value that represents each road infrared signal, with the luminosity parameter at guiding point place luminous intensity for example i, illumination eor brightness lbe directly proportional, formula (7), (8), (9) can be unified to be written as:

　　　　　

。

For the angle of pitch of transmitting tube, be the array that 0 °, optical axis are positioned at same plane, azimuth is calculated and is simplified (referring to Fig. 5 (a)): establish 2 transmitting tube A and the azimuth of B in emission array is respectively -Δ φwith Δ φ, the light intensity value that guiding point place detects is respectively i _a with i _b (function curve diagram is calculated at the azimuth with reference to Figure 14 (b)).

According to formula (5), obtain:

　　　　　

Two formula both sides are done respectively minferior extracting operation obtains:

　　　　　

Note

　　　　　

Utilize trigonometric function formula carry out and, poor, than computing, obtain:

　　　　　

Negate trigonometric function obtains:

　　　　　

So azimuth of guiding point φcomputing formula be:

　　　　　

For brightness value eor brightness value l, can derive the computing formula of same form:

　　　　　

(9)

Wherein fthe measured value that represents each road infrared signal.

With same algorithm, can obtain:

For 4 transmitting tube A, the C, E, the G that arrange according to cross in Fig. 4, the azimuth in emission array is respectively 0 °, 90 °, 180 °, 270 °, azimuth φcomputing formula be:

　　　　　 (10)

For 4 transmitting tube B, the D, F, the H that arrange according to X-shaped in Fig. 4, the azimuth in emission array is respectively 45 °, 135 °, 225 °, 315 °, and the computing formula of azimuth φ is:

　　　　　

(11)

For evenly distributed according to regular polygon or circle nindividual transmitting tube (for example, in the regular hexagon array that in Fig. 6,6 infrared emission tubes are arranged in, Fig. 48 octagon arrays that infrared emission tube is arranged in), azimuth φcomputing formula be:

　　　　　 (12)

Wherein fthe measured value that represents each road infrared signal.

These azimuth algorithms are listed in table 2 with unified form:

The azimuth algorithm of table 2 guiding point

。

Because infrared receiver is processed and is positioned at guide end with corresponding signal, need to various control commands and data be sent to mobile terminal by other remote control channel, realize accordingly and controlling.

Referring to Fig. 2, guide end is installed remote control transmitter 7, and receiver of remote-control sytem 6 is installed in mobile terminal.The EFFECTIVE RANGE of remote signal 15 is greater than the scope of infrared ray orientation detection signal 3, theaomni-directional transmission and reception, the transmitting of assurance remote control command and data.The signal transmitting comprises the formation switching signal, transmission power adjustment signal, synchronizing signal of bearing data, signal strength signal intensity (relative distance) data, motion carrier homing guidance signal, infrared emitting array etc.

Remote control mode comprises wireless remotecontrol, infra-red remote control, ultra-sonic remote control or wired remote control etc., can adopt general multichannel proportional remote control equipment.While adopting infra-red remote control mode, for avoiding the infrared signal of using with orientation detection to interfere with each other, should adopt different carrier frequencies or adopt time division multiplexing working method.

Synchronizing signal transmits between mobile terminal and guide end, for determining that each road pulse signal is in the sequential position of frame, the corresponding relation between each pulse that guarantees to transmit and receive.

As shown in Figure 7, synchronizing signal is sent by mobile terminal, and the pulse signal of using with orientation detection is the same, takes the mode of infrared emitting.Special-purpose infrared synchronous signals transmitting tube 71 is set in infrared emitting array 12, relative other transmitting tube at right angle setting, there is the larger angle of departure and transmitting power, the effective range of the infrared synchronous signals 70 of transmitting is greater than the scope of orientation detection signal, guarantees the reliable reception of synchronizing signal.

Or all or part of infrared emission tube in infrared emitting array is launched infrared synchronous signals in the mode of launching simultaneously, the signal strength signal intensity that receiving terminal receives, by being not less than any one transmitting tube signal strength signal intensity of transmitting separately, meets the requirement of synchronizing signal transmitting.

Lock-out pulse must with orientation detection pulse difference, the minimum pulse width of the lock-out pulse of infrared receiver output or maximum pulse or the amplitude that amplitude must be greater than orientation detection pulse, such as pulsewidth large 1 times or amplitude large 1/3 etc.Referring to Figure 12, receiving terminal detects after synchronizing signal 121, and the clock generator 120 that multiple signals sync separator 123 is used is synchronously adjusted, and keeps synchronous regime with transmitting terminal.

Synchronizing signal also can be sent by remote control channel by guide end, referring to Fig. 2, adopt the form identical with other remote signal 15, by remote control transmitter 7, sent, mobile terminal receives after synchronizing signal 121 by receiver of remote-control sytem 6, the transmitting of sequencing control infrared ray orientation detection signal 3 according to the rules.

The optical axis of the infrared receiver of guide end points to the guiding point that is positioned at certain position, space, detects the intensity of Gai Chuge road infrared signal.But this guiding point is also invisible, therefore adopt the light-emitting diode (LED) 166 of transmitting visible ray, transmitting white and column of colour, form the guiding hot spot 16 centered by guiding point 8, indication guiding position and direction.

Figure 16 is white light and color LED array and the structure chart of guiding hot spot.White light LEDs and the color LED such as red, orange, yellow, green, blue, purple form array 160, centered by infrared receiver 2, evenly arrange, and the optical axis of each LED166 is parallel with the optical axis of infrared receiver 2.

LED array also comprises the light distributing system 167 being comprised of lens, speculum, projection eyeglass etc.Lens, speculum etc. form condenser system, improve irradiation brightness and the distance of LED; Projection eyeglass projects various figures, pattern 163.

The brightness of illumination of the white light of white light LEDs transmitting is high, forms white guiding hot spot 161; The colourama of color LED transmitting forms colored hot spot 162, has various color lamp pattern effects; Various figures, pattern 163 that projection eyeglass projects are replaceable.

LED array adopts control, the drive circuit 165 of LED flashlight and LED color lamp, has brightness regulation, the functions such as various flash modes and color lamp pattern effect are set.

Figure 17 is a kind of global design figure of guide end, adopts the bar-shaped form-making design of guide of flashlight type.Anterior center installation infrared line receiver 2, installs white light and color LED array component 160 around, and circuit board 170 and battery 177 are equipped with in middle part, and afterbody is equipped with remote control transmitter and antenna 7, and the operating knobs such as various buttons, knob, switch are installed on shell.

Various operating knobs comprise:

Guiding button 173: while pressing, guide end is guided operation to mobile terminal;

Brightness regulation knob 172: regulate the white of LED array and the brightness of column of colour;

Color lamp arranges key 171: the various color lamp pattern effects of LED array etc. are set;

Other operating key, operation keys and switch etc.: other function setting and the operation of completion system, such as mains switch etc.

Battery 177 can adopt dry cell, lead accumulator, lithium battery etc.

Guide end can also adopt the parts such as analog switch, digital regulation resistance, computer interface, and the remote controller of using with existing telecontrolled model is connected, and is combined into multi-functional remote controller.

The mounting means of the infrared emission tube array of mobile terminal on motion carrier can be divided into distributed conformal installation and centralized installation.

In distributed conformal mounting means, each transmitting tube in infrared emitting array is according to array configurations requirement, the front, back, left, right, up, down etc. that is arranged on respectively the housing of motion carrier with certain angle is located, the relevant position of surface of shell arranges infrared ray window, the infrared ray light transmission piece that identical with carrier surface shape (conformal) is installed, enclosure interior is installed light shield, shadow shield etc. as required.

In the centralized mounting means shown in Figure 19, infrared emission tube array is installed concentratedly in the optics cover 190 arranging separately.Optics cover 190 is erected at top of motion carrier etc. and locates, and adopts the moulding such as dish-shaped, spherical, disc.Each infrared emitting pipe unit 196 of the middle part installation infrared line emission array of optics cover 190 housings, the rotating trace 193 of installation position angle, top indicator light 191, signal strength signal intensity (relative distance) bar 192, radar type etc., bottom is the connecting lines 197 such as mounting bracket 199 and holding wire, power line; Inner mounting circuit boards 198 assemblies such as grade of optics cover 190, also have sound-producing device, such as buzzer or loudspeaker etc.

Infrared ray optical direction remote control system of the present invention has photoelectricity orientation detection and tracking, guidance function, detects distance, can reach the distance order of magnitude of common infra-red remote control, has higher accuracy; Simple to operate, only need will guide rod to point to guiding position; Volume is little, and cost is low.

This system tool has been widely used, be for example applied in remote control model car, toy car, climb on wall car, by guiding hot spot pilot model car advance, retreat, turning, acceleration and deceleration etc.; Be applied on toy robot the moving direction of control and action; Be applied on toy for animal, with objects such as guiding hot spot simulation small game, roller balls, induction toy animals model makes and turning round, approaches, flutter and the action such as catch.

Claims (16)

1. an infrared ray optical direction remote control system, is comprised of guide end and mobile terminal two parts, it is characterized in that: on the motion carrier of mobile terminal, by a plurality of infrared emission tubes, form array, timesharing is the multiplex infrared signal of launch azimuth detection use successively; Guide end is installed a highly sensitive infrared receiver, serial received also detects the parameter of each road infrared signal, obtains azimuth information, formation control command signal after data computing, by remote control transmitter, send to mobile terminal again, controlled motion carrier is followed the tracks of, is guided;

Guiding hot spot indication guiding position and the direction of visible ray for guide end; Between mobile terminal and guide end, transmit synchronizing signal, keep transmitting and receiving the synchronous corresponding relation of Ge road signal.

2. infrared ray optical direction remote control system according to claim 1, is characterized in that: the composition of mobile terminal comprises infrared emission tube array, pulse signal generator, multiple signals synchronous distributor, carrier modulation and power driving circuit, receiver of remote-control sytem, motion carrier; The composition of guide end comprises infrared receiver, multiple signals sync separator, pulse parameter measure, the computing of azimuth information data, control signal generation, remote control transmitter, white light and color LED array; Wherein the computing of azimuth information data and control signal produce function and also can be configured in mobile terminal;

Mobile terminal forms infrared emitting array by a plurality of infrared emission tubes; Pulse signal generator produces the pulse train with certain pulse duration and interval; Under the effect of synchronizing signal, by multiple signals synchronous distributor, each pulse cycle in pulse train is assigned to the drive circuit of each transmitting tube, through carrier modulation, timesharing is launched successively;

Each road infrared signal, through straightline propagation or by ground, the diffuse reflection of wall body surface, forms the infrared ray light intensity distribution that orientation detection is used in space;

Each road infrared pulse signal of the infrared receiver serial received of guide end, after amplifying, pulse parameter of output is along with the pulse train of the luminosity parameter variation of infrared signal; Under the effect of synchronizing signal, according to the order identical with transmitting terminal, by multiple signals sync separator Jiang Ge road pulse signal, from pulse train, separated, carry out respectively the measurement of pulse parameter;

Then Dui Ge road signal value carries out data computing, obtains azimuth and out of Memory, produces control command signal, and the actuating mechanism on controlled motion carrier is carried out corresponding action, to guiding point, moves;

Guide end is installed remote control transmitter, and receiver of remote-control sytem is installed in mobile terminal, and various control commands and data are sent to mobile terminal from guide end;

White light and color LED array transmitting visible light beam for guide end, form the guiding hot spot centered by guiding point;

Between mobile terminal and guide end, transmit synchronizing signal.

3. infrared ray optical direction remote control system according to claim 1, is characterized in that: a plurality of infrared emission tubes at spatial arrangement, form infrared emission tube array according to certain geometry;

Between the optical axis of each transmitting tube, shape is at a certain angle, and phase pair array basic point, orienting line or diffuse surface have specific azimuth and the angle of pitch; The infrared ray of transmitting, space crossed overlapping, forms the spatial light intensity distribution that orientation detection is used;

In infrared emitting array, also comprise dipped beam and distance light transmitting tube, auxiliary angle measurement transmitting tube, synchronizing signal transmitting tube.

4. infrared ray optical direction remote control system according to claim 1, is characterized in that: all or part of transmitting tube in infrared emission tube array, and according to certain order and combination, timesharing launch azimuth detects the infrared pulse signal of use;

When search pattern, all transmitting tube is launched successively, omnidirectional's scanning; When tracing mode, only have the part transmitting tube timesharing transmitting for following the tracks of, improve transmitting repetition rate; Also has the transmitting respectively of short range, long-range, auxiliary angle measurement transmitting tube;

Firing order has ortho position order, phase contraposition order, ortho position built-up sequence.

5. infrared ray optical direction remote control system according to claim 1, it is characterized in that: mobile terminal is according to power control signal, by constant-current source circuit, change the forward operating current of infrared emission tube, or by PWM device, change the width of carrier pulse, regulate the transmitting power of infrared emitting array.

6. infrared ray optical direction remote control system according to claim 1, it is characterized in that: only use infrared receiver serial received infrared emission tube array time-sharing transmitting Ge road infrared signal, all signals all pass through same optical system and photo-electric conversion element reception, by single pass amplifier, amplified and pulse signal forms processing of circuit.

7. infrared ray optical direction remote control system according to claim 1, it is characterized in that: the optical system of infrared receiver is carried out the detection of luminosity parameter to the luminous intensity of direct projection or Diffused IR, illumination or brightness, with reference to the design of photometer, illuminance meter or luminance meter optical system; Adopt the amplifier of highly sensitive photoelectric cell and high-gain; Output signal strength has good linear relationship with the luminosity parameter of input infrared signal.

8. infrared ray optical direction remote control system according to claim 1, is characterized in that: guide end is installed remote control transmitter, and receiver of remote-control sytem is installed in mobile terminal, and various control commands and data are sent to mobile terminal from guide end; The EFFECTIVE RANGE of remote signal is greater than the scope of infrared ray orientation detection signal, theaomni-directional transmission and reception; Remote control mode adopts wireless remotecontrol, infra-red remote control, ultra-sonic remote control or wired remote control.

9. infrared ray optical direction remote control system according to claim 1, is characterized in that: between mobile terminal and guide end, transmit synchronizing signal, for determining that each road pulse signal is in the sequential position of frame, the corresponding relation between each pulse that guarantees to transmit and receive;

Mobile terminal is equipped with the device that is called multiple signals synchronous distributor, under the effect of synchronizing signal, each pulse cycle in frame pulse sequence is assigned to each infrared emission tube, successively transmitting;

Guide end is equipped with the device that is called multiple signals sync separator, under the effect of synchronizing signal, according to the order ，Jiang Ge road pulse signal identical with transmitting terminal, from the frame pulse sequence receiving, separates.

10. infrared ray optical direction remote control system according to claim 1, is characterized in that: synchronizing signal is sent by mobile terminal, and the pulse signal of using with orientation detection is the same, takes the mode of infrared emitting, but pulse duration or amplitude are larger;

Special-purpose infrared synchronous signals transmitting tube is set in infrared emitting array, and the effective range of the synchronizing signal of transmitting is greater than the scope of infrared ray orientation detection signal; Or all or part of infrared emission tube in emission array is launched infrared synchronous signals in the mode of launching simultaneously;

Guide end detects identification according to pulse duration or amplitude to lock-out pulse.

11. infrared ray optical direction remote control systems according to claim 1, it is characterized in that: the symmetrical scanning method that infrared emission tube array is adopted to the multi-pulse repetition period, frame signal Zhong Ge road transmitted pulse is symmetrical, pulse repetition period is different, and receiving terminal is determined the corresponding relation of synchronizing signal He Ge road pulse by detecting the repetition period of pulse signal.

12. infrared ray optical direction remote control systems according to claim 1, is characterized in that: synchronizing signal is sent by remote control channel by guide end, adopt the form identical with other remote signal, by remote control transmitter, are sent; Mobile terminal receives after synchronizing signal by receiver of remote-control sytem, the transmitting of sequencing control infrared ray orientation detection signal according to the rules.

13. infrared ray optical direction remote control systems according to claim 1, is characterized in that: adopt the light-emitting diode of transmitting visible ray to form array, transmitting white and column of colour, form the visible guiding hot spot centered by guiding point;

The light-emitting diode that forms array comprises white light LEDs and color LED, centered by infrared receiver, evenly arranges, and the optical axis of each LED is parallel with the optical axis of infrared receiver;

By lens, speculum, projection eyeglass, form light distributing system; Lens, speculum form condenser system, improve irradiation brightness and the distance of LED, and projection eyeglass projects various figures, pattern;

The beam brightness of LED array is adjustable, and color lamp pattern effect can arrange, and figure, the pattern of projection are replaceable.

14. infrared ray optical direction remote control systems according to claim 1, is characterized in that: guide end adopts the bar-shaped form-making design of guide of flashlight type; Anterior center installation infrared line receiver, white light and color LED array component are around installed, and circuit board and battery are equipped with in middle part, and afterbody is equipped with remote control transmitter antenna, various operating knobs are installed on shell, are comprised that guiding button, brightness regulation knob, color lamp arrange key, mains switch.

15. infrared ray optical direction remote control systems according to claim 1, it is characterized in that: in distributed conformal mounting means, each transmitting tube in infrared emitting array is according to array configurations requirement, with certain angle, be arranged on respectively motion carrier housing front, back, left, right, up, down everywhere, the relevant position of surface of shell arranges infrared ray window, the infrared ray light transmission piece identical with carrier surface shape is installed, and enclosure interior is installed light shield, shadow shield as required.

16. infrared ray optical direction remote control systems according to claim 1, is characterized in that: in centralized mounting means, infrared emission tube array is installed concentratedly in the optics cover arranging separately;

Optics cover is erected at the top of motion carrier; Moulding has dish, spherical, disc; Each infrared emitting pipe unit of the middle part installation infrared line emission array of optics over body case, top is provided with the rotating trace of azimuth indicator light, signal strength signal intensity bar, radar type, bottom is mounting bracket and connecting line, and connecting line comprises holding wire and power line; The inner mounting circuit boards of optics cover.

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