Summary of the invention
The object of the invention is to, a kind of acoustic control multi-functional glasses is provided, these glasses are by single-chip microcomputer, voice recognition chip, speech chip, microphone, earphone, battery, ultrasonic distance-measuring sensor, infrared emission tube, laser diode, can realize the selection that acoustic control completes glasses function automatically, but also can acoustic control ultrasonic ranging, the infrared ray of acoustic control launching code, acoustic control Emission Lasers, make it expand range of application.
For achieving the above object, technical scheme of the present invention is as follows:
A kind of acoustic control multi-functional glasses, comprise picture frame, mirror leg, single-chip microcomputer, ultrasonic distance-measuring sensor, speech chip, battery, keyswitch, earphone, wherein, also comprise voice recognition chip, audio amplifier circuit, microphone, infrared emission tube, laser diode, this voice recognition chip respectively with described single-chip microcomputer, described audio amplifier circuit, described battery, described earphone, described infrared emission tube, described laser diode connects, described microphone is connected with described voice recognition chip by described audio amplifier circuit, described voice recognition chip has been used for speech recognition and has realized acoustic control, described ultrasonic distance-measuring sensor, described infrared emission tube, described laser diode are arranged on described picture frame, and described single-chip microcomputer, speech chip, voice recognition chip, earphone, microphone, battery, described audio amplifier circuit, keyswitch are arranged on described mirror leg.
Preferably, the model of described voice recognition chip is HBR210.
Preferably, the model of described ultrasonic distance-measuring sensor is KS103, and this ultrasonic distance-measuring sensor is used for obtaining supersonic sounding value.
Preferably, the model of described speech chip is SC8035, and this speech chip is for automatic information broadcast supersonic sounding value, voice message, voice answer-back playback dialogue.
Preferably, the lithium battery that described battery is 3.6V.
Preferably, the model of described single-chip microcomputer is W79E825A
.
Preferably, the model of described single-chip microcomputer is W79E824A
.
Beneficial effect of the present invention:
A kind of acoustic control multi-functional glasses of the present invention, these glasses are by single-chip microcomputer, voice recognition chip, speech chip, microphone, earphone, battery, ultrasonic distance-measuring sensor, infrared emission tube, laser diode, can realize the selection that acoustic control completes glasses function automatically, but also can acoustic control ultrasonic ranging, the infrared ray of acoustic control launching code, acoustic control Emission Lasers; Such as, can realize the infrared ray that described acoustic control ultrasonic ranging can realize the function of acoustic control range finding, described acoustic control the launching code function of acoustic control Infrared remote controller, described acoustic control Emission Lasers can realize the function of acoustic control laser pen, make it expand range of application.
Embodiment
In order to further illustrate principle of the present invention and structure, existing by reference to the accompanying drawings to a preferred embodiment of the present invention will be described in detail, but described embodiment is only for furnishing an explanation and the use of explaining, can not be used for limiting scope of patent protection of the present invention.
As Fig. 1, a kind of acoustic control multi-functional glasses shown in Fig. 2, comprise left side picture frame 9, right side picture frame 9A, left side mirror leg 10, right side mirror leg 10A, model is the single-chip microcomputer 1 of W79E825A, model is the ultrasonic distance-measuring sensor 5 of KS103, model is the speech chip 2 of SC8035, the lithium battery 4 of 3.6V, keyswitch K1, keyswitch K2, earphone 2B, earphone 3J, wherein, also comprise voice recognition chip 3, audio amplifier circuit 6, microphone 3K, infrared emission tube 7, laser diode 8, this voice recognition chip 3 respectively with described single-chip microcomputer 1, described audio amplifier circuit 6, described battery 4, described earphone 3J, described infrared emission tube 7, described laser diode 8 connects, described microphone 3K is connected with described voice recognition chip 3 by described audio amplifier circuit 6, described voice recognition chip 3 is realized acoustic control for completing speech recognition, described ultrasonic distance-measuring sensor 5 is arranged on described left side picture frame 9, described infrared emission tube 7, described laser diode 8 are arranged on described right side picture frame 9A, described single-chip microcomputer 1, speech chip 2, battery 4, earphone 2B are arranged on described right side mirror leg 10A, described voice recognition chip 3, earphone 3J, audio amplifier circuit 6, keyswitch K1, keyswitch K2 are arranged on described left side mirror leg 10, and described microphone 3K is arranged on described left side mirror leg 10 by support bar.
The 2nd pin of described voice recognition chip 3, the 24th pin, the emitter of triode 3Q, one end pin of microphone 3K, the negative pole pin of 10 μ F capacitor 3N are connected with the negative pole of described battery 4 jointly; The 3rd pin, the 4th pin of described voice recognition chip 3 are connected with the 6th pin of described voice recognition chip 3 by 4700PF capacitor 3F, 20K Ω resistance 3G, and the 6th pin of described voice recognition chip 3 is also connected with the 7th pin of described voice recognition chip 3 by 10K Ω resistance 3H, 0.1 μ F capacitor 3I; The 23rd pin of described voice recognition chip 3 is connected with the negative pole of described battery 4 by 1000PF capacitor 3D, and the negative pole of described battery 4 is also connected with the 26th pin of described voice recognition chip 3 by 0.1 μ F capacitor 3B.
The 11st pin of described voice recognition chip 3 is by 0.01 μ F capacitor 3E, 100K Ω resistance 3T is connected with the negative pole of described battery 4, the 11st pin of described voice recognition chip 3 is also connected with the 27th pin of this voice recognition chip 3 by 91K Ω resistance 3U, the 11st pin of described voice recognition chip 3 is also connected with the collector of described triode 3Q by 0.1 μ F capacitor 3S, the collector of this triode 3Q is also connected with the 27th pin of described voice recognition chip 3 by 3K Ω resistance 3R, the collector of described triode 3Q is also connected with the base stage of this triode 3Q by 470K Ω resistance 3P, the base stage of this triode 3Q is connected with the other end pin of described microphone 3K by 0.1 μ F capacitor 3M, the other end pin of described microphone 3K is also connected with the anodal pin of 10 μ F capacitor 3N by 3K Ω resistance 3L, the anodal pin of described 10 μ F capacitor 3N is also connected with the 27th pin of described voice recognition chip 3 by 2K Ω resistance 3W.
The 28th pin of described voice recognition chip 3 is the DATA pin of voice identification result two-wire serial output, and the 28th pin of this voice recognition chip 3 is connected with the 10th pin of described single-chip microcomputer 1; The 30th pin of this voice recognition chip 3 is the CLK pin of speech recognition two-wire serial output, and the 30th pin of this voice recognition chip 3 is connected with the 9th pin of described single-chip microcomputer 1; The 32nd pin of this voice recognition chip 3 is speech recognition dormancy, wakes input control pin up, and the 32nd pin of this voice recognition chip 3 is connected with the 8th pin of described single-chip microcomputer 1; The 31st pin of described voice recognition chip 3 is connected with the negative pole of described laser diode 8, and the positive pole of described laser diode 8 is connected with the positive pole of described battery 4, and the 31st pin of described voice recognition chip 3 is for laser diode 8 Emission Lasers described in acoustic control; The 35th pin of described voice recognition chip 3 is connected with the negative pole of described infrared emission tube 7, the positive pole of described infrared emission tube 7 is connected with the positive pole of described battery 4, and the 35th pin of described voice recognition chip 3 is for the infrared ray of infrared emission tube 7 launching codes described in acoustic control.
The 1st pin, the 25th pin of described voice recognition chip 3 are connected with the positive pole of described battery 4 jointly, and the 20th pin, the 21st pin of this voice recognition chip 3 are connected with the positive pole of described battery 4 by resistance 3Y jointly; The 22nd pin of this voice recognition chip 3 is connected with the positive pole of described battery 4 by resistance 3Z, the 22nd pin of this voice recognition chip 3 is also connected with the negative pole of described battery 4 by capacitor 3C, and the negative pole of this battery 4 is also connected with the positive pole of this battery 4 by capacitor 3A; The 43rd pin, the 44th pin of described voice recognition chip 3 are connected with anodal pin, the negative pole pin of earphone 3J respectively.
Described audio amplifier circuit 6 comprises that model is 9014 transistor 3Q, 3K Ω resistance 3L, 2K Ω resistance 3W, 3K Ω resistance 3R, 91K Ω resistance 3U, 100K Ω resistance 3T, 470K Ω resistance 3P, 0.01 μ F capacitor 3E, 0.1 μ F capacitor 3S, 0.1 μ F capacitor 3M, 10 μ F capacitor 3N, described triode 3Q base stage is connected with the other end pin of described microphone 3K by 0.1 μ F capacitor 3M, and one end pin of this microphone 3K is connected with the negative pole of described battery 4; The other end pin of described microphone 3K is also connected with the anodal pin of 10 μ F capacitor 3N by 3K Ω resistance 3L, and the anodal pin of this 10 μ F capacitor 3N is also connected with the 27th pin of voice recognition chip 3 by 2K Ω resistance 3W; The emitter of triode 3Q is connected with the negative pole of described battery 4, the collector of this triode 3Q is connected with the 11st pin of described voice recognition chip 3 by 0.1 μ F capacitor 3S, and the 11st pin of this voice recognition chip 3 is also connected with the negative pole of described battery 4 by 100K Ω resistance 3T, 0.01 μ F capacitor 3E; The collector of described triode 3Q is also connected with the base stage of described triode 3Q by 470K Ω resistance 3P, and the collector of described triode 3Q is also connected with the 27th pin of described voice recognition chip 3 by 3K Ω resistance 3R.
The 1st pin of described single-chip microcomputer 1, the 2nd pin respectively with keyswitch K1, one end pin of K2 connects, described keyswitch K1, the other end pin of K2 is connected with the negative pole of battery 4 jointly, the negative pole of described battery 4 also with the 5th pin of described single-chip microcomputer 1, the pin GND of described ultrasonic distance-measuring sensor 5, the pin VSS of described speech chip 2, one end of capacitor 2A connects, the other end of this capacitor 2A is connected with the pin VREG of described speech chip 2, the pin PWM1 of described speech chip 2, PWM2 respectively with the positive pole of earphone 2B, negative pole pin connects, the pin BUSY of described speech chip 2, DATA, RST respectively with the 17th pin of described single-chip microcomputer 1, the 18th pin, the 19th pin connects, the pin VDD of described speech chip 2 is connected with the positive pole of described battery 4, the positive pole of described battery 4 is also connected with one end of pin VCC, the resistance 5A of the 15th pin of described single-chip microcomputer 1, described ultrasonic distance-measuring sensor 5, one end of resistance 5B, and the other end of described resistance 5A is connected with the 12nd pin of described single-chip microcomputer 1, the pin SDA of described ultrasonic distance-measuring sensor 5 respectively, the other end of described resistance 5B is connected with the 11st pin of described single-chip microcomputer 1, the pin SCL of described ultrasonic distance-measuring sensor 5 respectively.
Preferably, the model of described voice recognition chip 3 is HBR210.
Preferably, the model of described ultrasonic distance-measuring sensor 5 is KS103, and this ultrasonic distance-measuring sensor 5 is for obtaining supersonic sounding value.
Preferably, the model of described speech chip 2 is SC8035, and this speech chip 2 is for automatic information broadcast supersonic sounding value, voice message, voice answer-back playback dialogue.
Preferably, the lithium battery that described battery 4 is 3.6V.
Preferably, the model of described single-chip microcomputer 1 is W79E825A
.
Preferably, the model of described single-chip microcomputer 1 is W79E824A
.
Described embodiment advantage and beneficial effect are, this embodiment acoustic control multi-functional glasses, the single-chip microcomputer that these glasses are W79E825A by model, the voice recognition chip that model is HBR210, speech chip that model is SC8035, microphone, earphone, the lithium battery of 3.6V, ultrasonic distance-measuring sensor, infrared emission tube, the laser diode that model is KS103, can realize the selection that acoustic control completes glasses function automatically, but also can acoustic control ultrasonic ranging, the infrared ray of acoustic control launching code, acoustic control Emission Lasers; Such as, can realize the infrared ray that described acoustic control ultrasonic ranging can realize the function of acoustic control range finding, described acoustic control the launching code function of acoustic control Infrared remote controller, described acoustic control Emission Lasers can realize the function of acoustic control laser pen, make it expand range of application.
The just embodiment of this invention described above; various not illustrating limited essence of an invention Composition of contents; person of an ordinary skill in the technical field read after instructions can to before described embodiment make an amendment or be out of shape, all should be considered as belonging to protection scope of the present invention.