CN204115856U - A kind of heterodyne interference type vialog based on laser doppler - Google Patents

Abstract

Based on a heterodyne interference type vialog for laser doppler, comprise light source assembly, optical interference circuit assembly and signal processing component.Light source assembly is made up of dual-frequency laser source, polarization splitting prism, catoptron and the polarizer; Optical interference circuit assembly is made up of unpolarized Amici prism, right-angle prism and the curved surface prism be arranged on tested vibrating object; Signal processing component for receiving the two beam interferometer light launched from Amici prism unpolarized in optical interference circuit assembly, and converts interference light signal to electric signal and processes, and obtains the vibration information of tested vibrating object.The vialog that the utility model provides, can improve vibration survey precision.

Description

A kind of heterodyne interference type vialog based on laser doppler

Technical field

The utility model belongs to Vibration measuring technique using laser interferometer field, particularly a kind of heterodyne interference type vialog based on laser doppler.

Background technology

Along with developing by leaps and bounds of modern project technology, the particularly development of the technology such as Aeronautics and Astronautics, oceanographic engineering, machine-building, need to carry out high-acruracy survey to gather vibration signal to vibration, and process the response data in operational process in real time, thus vibration & noise analysis is carried out to mechanical structure system.What vibration survey was conventional has electrostatic capacitive, eddy current type, laser triangulation, piezoelectric type and laser-Doppler mode.Laser doppler vibration measuring technology is a kind of technology of being carried out high precision vibration detection by the interference of laser, compare other method and have that precision is high, dynamic response is fast, far measuring distance, measurement range are large, the non-cpntact measurement (object vibration that can rotate for surface, high temp objects vibration and the vibration of miniature object structures detect), there is no mechanical resonant (being thus applicable to the vibration of high frequency, little amplitude), can the advantages such as object properties be reflected by the inverting of vibration characteristics, be the important developing direction of in current vibration test technology one.

The existing linearly polarized light that polarization direction is mutually orthogonal, frequency component is different utilizing optical element to be sent by laser instrument based on the heterodyne interference type light path of laser doppler is divided into two bundles, and this two-beam is still mutually orthogonal containing polarization direction, that frequency component is different linearly polarized light.Wherein there is Doppler effect via after the catoptron reflection be fixed on vibrating object or after directly being reflected by vibrating object to be measured in light beam, again converge with another light beam again and interfere, acquisition interference information, is then changed by signal and processing components records vibration information.A kind of high precision double frequency that application discloses being CN103499385A as publication number measures laser heterodyne interference phase place vibration measuring light path simultaneously, by the first semi-transparent semi-reflecting lens, the laser beam that double-frequency laser source sends is divided into reflected light and transmitted light, wherein reflected light irradiates and enters the 3rd semi-transparent semi-reflecting lens, transmitted light is after the second semi-transparent semi-reflecting lens fractional transmission, be irradiated to body surface and reflect, the reflected light generation Doppler shift of body surface and by the second semi-transparent semi-reflecting lens part reflection, the light launched by the second semi-transparent semi-reflecting lens is by entering the 3rd semi-transparent semi-reflecting lens after half-wave plate and completely reflecting mirror, light beam is merged into the reflected light of the first semi-transparent semi-reflecting lens.Because the light beam in this difference interference phase place vibration measuring light path there occurs the mixing phenomena of frequency and polarization state in the optical path, and putting of optical device cannot accomplish desirable aligned condition, therefore still there will be comparatively big error.

Utility model content

The purpose of this utility model is for the deficiencies in the prior art, provides a kind of heterodyne interference type vialog based on laser doppler, to improve vibration survey precision.

Heterodyne interference type vialog based on laser doppler described in the utility model, comprises light source assembly, optical interference circuit assembly and signal processing component.

Light source assembly is made up of dual-frequency laser source, polarization splitting prism, catoptron and the polarizer; Described polarization splitting prism is positioned in the light path of dual-frequency laser source, and the light beam sent by dual-frequency laser source is divided into the linearly polarized light that two bundle frequencies are different, direction of vibration is vertical; Described catoptron is positioned in the light path of wherein a branch of linearly polarized light, for the direction of propagation of this bunch polarized light is adjusted to parallel with the direction of propagation of another bunch polarized light; The described polarizer is positioned in the light path of two parallel bunch polarized lights of the direction of propagation, for being adjusted to identical by the direction of vibration of two bunch polarized lights;

Optical interference circuit assembly is by unpolarized Amici prism, right-angle prism and curved surface prism (during use, curved surface prism is arranged on tested vibrating object or near vibration source and installs) composition; Described unpolarized Amici prism is arranged in the light path of the polarizer of light source assembly, for by from the polarizer and the two bundle parallel lines polarized lights impinging perpendicularly on its surperficial non-central location are divided into two bundle reflected light and two bundle transmitted lights, described reflected light is reference light, and described transmitted light is flashlight; Described right-angle prism is positioned in the light path of two bundle reference lighies, for the two bundle reference lighies entering right-angle prism are reflected back unpolarized Amici prism, and the reference light that the reference light that unpolarized Amici prism is launched and right-angle prism are reflected back unpolarized Amici prism is not total to light path; Described curved surface prism is positioned in the light path of two bundle flashlights, for the relative position exchange back reflection of the two bundle flashlights entering curved surface prism is returned unpolarized Amici prism, and the flashlight that unpolarized Amici prism is launched is not total to light path with the flashlight being reflected back unpolarized Amici prism from curved surface prism; In unpolarized Amici prism, the reference light being reflected back unpolarized Amici prism from right-angle prism interferes with the flashlight being reflected back unpolarized Amici prism from curved surface prism, forms two beam interferometer light;

Signal processing component for receiving the two beam interferometer light launched from Amici prism unpolarized in optical interference circuit assembly, and converts interference light signal to voltage signal and processes, and obtains the vibration information of tested vibrating object.

The above-mentioned heterodyne interference type vialog based on laser doppler, described polarization splitting prism, unpolarized Amici prism are Single wavelength Amici prism.

The above-mentioned heterodyne interference type vialog based on laser doppler, the described polarizer is linear polarizer.

The above-mentioned heterodyne interference type vialog based on laser doppler, described catoptron is Single wavelength deielectric-coating high reflection mirror.Described high reflection mirror refers to the catoptron of reflectivity more than 90%.

The above-mentioned heterodyne interference type vialog based on laser doppler, described signal processing component comprises:

First photodetector and the second photodetector, for receiving two beam interferometer light respectively and converting two beam interferometer light signals to voltage signal respectively;

Frequency discriminator, is converted into the change of resultant voltage amplitude and exports resultant voltage signal for the phase differential that detects from two groups of voltage signals of the first photodetector and the second photodetector by the change of described phase differential;

Low-pass filter, for filtering from the high frequency noise in the voltage signal of frequency discriminator;

A/D converter, for being converted into digital signal by the analog voltage signal after filter away high frequency noise;

Computer system, for the process of digital signal;

Described first photodetector is connected with the input end of frequency discriminator with the output terminal of the second photodetector, the output terminal of frequency discriminator is connected with the input end of low-pass filter, the output terminal of low-pass filter is connected with the input end of A/D converter, and the output terminal of A/D converter is connected with computer system.

The light path of vialog described in the utility model is as follows:

The light beam that laser instrument sends is respectively f by being divided into two bundle frequencies after polarization splitting prism ₁, f ₂, linearly polarized light that direction of vibration is vertical, wherein a branch of linearly polarized light is parallel with another bunch polarized light direction of propagation after catoptron reflection, the two parallel linearly polarized lights in the bundle directions of propagation, by parallel injection behind polarizer adjustment polarization direction, form that two bundles are spatially separated from each other, polarization direction is identical, the direction of propagation is parallel and have the linearly polarized light of certain frequency difference.Above-mentioned two bunch polarized lights impinge perpendicularly on the non-central location of unpolarized Amici prism, are divided into reflected light and transmitted light by unpolarized Amici prism, and described reflected light is as reference light, and described transmitted light is as flashlight.Reference light is reflected back unpolarized Amici prism through right-angle prism after entering right-angle prism again, and the reference light that the reference light that unpolarized Amici prism is launched and right-angle prism are reflected back unpolarized Amici prism is not total to light path; Flashlight enters curved surface prism and be reflected back unpolarized Amici prism again after exchanging relative position, and the flashlight that the flashlight that unpolarized Amici prism is launched and curved surface prism are reflected back unpolarized Amici prism is not total to light path; Right-angle prism is reflected back the flashlight that the reference light of unpolarized Amici prism and curved surface prism be reflected back unpolarized Amici prism and interferes, and forms two beam interferometer light.Two beam interferometer light are converted to voltage signal by the first photodetector and the second photoelectric detector respectively, two groups of voltage signals input in frequency discriminator simultaneously, detect phase differential and the change of phase differential be converted into the change of resultant voltage amplitude and export resultant voltage signal, this voltage signal enters A/D converter after low-pass filter filtering radio-frequency component, input computer system after analog voltage signal being converted into digital signal by A/D converter to process, namely obtain the vibration information of tested vibrating object.

Compared with prior art, the utility model has following beneficial effect:

1, the linearly polarized light that a branch of polarization direction is mutually orthogonal, frequency component is different that the light source assembly of vialog described in the utility model utilizes polarization splitting prism, catoptron and the polarizer to be sent by dual-frequency laser source converts that two bundles are spatially separated, polarization direction is identical, the direction of propagation is parallel, have the linearly polarized light of certain frequency difference to, make the mixing of two-beam not occurrence frequency and polarization state, thus can avoid the error that the mixing phenomena of frequency and polarization state brings.Simultaneously, adopt a slice polarizer to regulate the polarization direction of two-beam in light source assembly simultaneously, the inner structure difference of the different polarizer and manual adjustments can be avoided to make the polarization direction of two-beam not identical thus the error brought, thus can improve vibration survey precision.

2, vialog described in the utility model makes the polarization direction from light source assembly identical, the direction of propagation is parallel, the two bunch polarized lights with certain frequency difference impinge perpendicularly on the non-central location of unpolarized Amici prism contained by optical interference circuit assembly, two-beam is divided into reference beam (folded light beam) and flashlight (transmitted light beam), and return in unpolarized Amici prism by right-angle prism contained by optical interference circuit assembly with reference to beam reflection, the reference beam launched from unpolarized Amici prism is made not to be total to light path with the reference beam being reflected back unpolarized Amici prism, be reflected back in unpolarized Amici prism again after making two bundle signal beams exchange relative position by curved surface prism contained by optical interference circuit assembly, the flashlight that the flashlight that unpolarized Amici prism is launched and curved surface prism are reflected back unpolarized Amici prism is not total to light path, in unpolarized Amici prism, right-angle prism is reflected back the flashlight that the reference light of unpolarized Amici prism and curved surface prism be reflected back unpolarized Amici prism and interferes, form two beam interferometer light.Compared with prior art, avoid the flashlight launched from unpolarized Amici prism and the flashlight light path altogether entering to inject unpolarized Amici prism, thus can reduce error when flashlight and reference light interfere in unpolarized Amici prism, improve measuring accuracy.

3, vialog light channel structure described in the utility model is simple, is convenient to optical path adjusting.

Accompanying drawing explanation

Fig. 1 is the structural representation of vialog described in the utility model;

Fig. 2 is the structural representation of the light source assembly in Fig. 1;

Fig. 3 is the perspective view of the optical interference circuit assembly in Fig. 1;

Fig. 4 is use publication number high precision double frequency disclosed in the patented claim of CN103499385A simultaneously to measure laser heterodyne interference phase place vibration measuring light path carries out measuring gained spectrogram to the analog vibration object that vibration frequency is 23Hz;

Fig. 5 is the spectrogram using vialog described in the utility model to carry out measuring gained to the analog vibration object that vibration frequency is 23Hz.

In figure, 1-dual-frequency laser source, 2-polarization splitting prism, 3-catoptron, the 4-polarizer, the unpolarized Amici prism of 5-, 6-right-angle prism, 7-curved surface prism, 8-first photodetector, 9-second photodetector, 10-frequency discriminator, 11-low-pass filter, 12-A/D converter, 13-computer system.

Embodiment

Below in conjunction with accompanying drawing, and by embodiment, the heterodyne interference type vialog based on laser doppler described in the utility model is described in further detail.

Embodiment 1

In the present embodiment, the structural representation of the described heterodyne interference type vialog based on laser doppler as shown in Figure 1, 2, 3, comprises light source assembly, optical interference circuit assembly and signal processing component.

Light source assembly is made up of dual-frequency laser source 1, polarization splitting prism 2, catoptron 3 and the polarizer 4, dual-frequency laser source 1 selects frequency difference to be the dual-frequency transverse Zeeman laser of 60MHz, emission wavelength is 633nm, polarization splitting prism 2 plates polarization beam splitter on inclined-plane, the ZF optical glass of four outside surface plating arrowband multi-layered antireflection coatings, applicable wavelengths is 633nm, catoptron 3 is Single wavelength deielectric-coating high reflection mirror (plated surface increases the k9 optical glass of anti-film), applicable wavelengths is 633nm, the linear polarizer that the polarizer 4 is made for dichroism material.As shown in Figure 2, described polarization splitting prism 2 is positioned in the light path of dual-frequency laser source 1 light path that the structure of light source assembly and each device are formed, and the light beam sent by dual-frequency laser source is divided into the linearly polarized light that two bundle frequencies are different, direction of vibration is vertical; Described catoptron 3 is positioned in the light path of wherein a branch of linearly polarized light, for the direction of propagation of this bunch polarized light is adjusted to parallel with the direction of propagation of another bunch polarized light; The described polarizer 4 is positioned in the light path of two parallel bunch polarized lights of the direction of propagation, for being adjusted to identical by the direction of vibration of two bunch polarized lights.

Optical interference circuit assembly is made up of unpolarized Amici prism 5, right-angle prism 6 and curved surface prism 7, unpolarized Amici prism 5 is k9 optical glass inclined-plane being coated with semi-permeable diaphragm, applicable wavelengths is 633nm, right-angle prism 6 increases anti-film for right-angle surface is coated with, inclined-plane is coated with the k9 optical glass of anti-reflection film, curved surface prism 7 is coated with the k9 optical glass increasing anti-film for curved inner surface; The light path that the structure of optical interference circuit assembly and each device are formed as shown in Figure 1, described unpolarized Amici prism 5 is arranged in the light path of the polarizer 4 of light source assembly, for by from the polarizer and the two bundle parallel lines polarized lights impinging perpendicularly on its surperficial non-central location are divided into two bundle reflected light and two bundle transmitted lights, described reflected light is reference light, and described transmitted light is flashlight; Described right-angle prism 6 is positioned in the light path of two bundle reference lighies, for the two bundle reference lighies entering right-angle prism are reflected back unpolarized Amici prism 5, and the reference light that the reference light that unpolarized Amici prism 5 is launched and right-angle prism are reflected back unpolarized Amici prism is not total to light path; Described curved surface prism 7 is positioned in the light path of two bundle flashlights, for the relative position exchange back reflection of the two bundle flashlights entering curved surface prism is returned unpolarized Amici prism 5, and the flashlight that unpolarized Amici prism 5 is launched is not total to light path with the flashlight being reflected back unpolarized Amici prism from curved surface prism; In unpolarized Amici prism 5, the reference light being reflected back unpolarized Amici prism from right-angle prism interferes with the flashlight being reflected back unpolarized Amici prism from curved surface prism, forms two beam interferometer light.

Signal processing component is made up of the first photodetector 8, second photodetector 9, frequency discriminator 10, low-pass filter 11, A/D converter 12 and computer system 13, first photodetector 8 and the second photodetector 9 all select silicon photocell, detection wavelength is 50 to 1100nm, response time is 10 to 50ns, gain is 10dB, frequency discriminator highest frequency 100Mhz, gain is 40dB, the cutoff frequency of low-pass filter is 100Hz, gain is 0dB, A/D converter resolution is 12, and transfer rate is 125ksps, and they are commercial goods.

Embodiment 2

The present embodiment uses the heterodyne interference type vialog based on laser doppler described in embodiment 1 to carry out Measurement on simulative oscillation.Measuring method is as follows:

1, take stereo set as vibration source, the curved surface prism 7 in heterodyne interference type vialog described in embodiment 1 is fixed in a box, this box be fixed on the loudspeaker front of stereo set and near loudspeaker, the vibration frequency of stereo set be adjusted to 23Hz.

2, open the dual-frequency laser source 1 in heterodyne interference type vialog described in embodiment 1 and make signal processing component in running order.

Measurement result is shown in Fig. 5.

Contrast test

Measure laser heterodyne interference phase place vibration measuring light path with publication number for the high precision double frequency disclosed in the patented claim of CN103499385A simultaneously carry out Measurement on simulative oscillation.Measuring method is as follows:

1, taking stereo set as vibration source, is tested vibrating object with reflective object, described reflective object is fixed on the loudspeaker front of stereo set and near loudspeaker, the vibration frequency of stereo set is adjusted to 23Hz.

2, open CN103499385A patented claim described in double frequency measure the dual-frequency laser source 101 in laser heterodyne interference phase place vibration measuring light path simultaneously and make photodetector, phase tester and supporting computer system be in duty.

Measurement result is shown in Fig. 4.

As can be seen from Figure 4, in spectrogram, except dominant frequency 23Hz, near 50Hz, also occurred some clutters, and amplitude and dominant frequency are closely.As can be seen from Figure 5, although also there are some clutters near 50Hz, 75Hz beyond dominant frequency 23Hz, its amplitude has differed larger with dominant frequency.

Above-mentioned measurement result shows, vialog described in the utility model and double frequency described in CN103499385A patented claim are measured compared with laser heterodyne interference phase place vibration measuring light path simultaneously, and measuring accuracy significantly improves.

Claims (9)

1., based on a heterodyne interference type vialog for laser doppler, comprise light source assembly, optical interference circuit assembly and signal processing component, it is characterized in that:

Light source assembly is made up of dual-frequency laser source (1), polarization splitting prism (2), catoptron (3) and the polarizer (4); Described polarization splitting prism (2) is positioned in the light path of dual-frequency laser source (1), and the light beam sent by dual-frequency laser source is divided into the linearly polarized light that two bundle frequencies are different, direction of vibration is vertical; Described catoptron (3) is positioned in the light path of wherein a branch of linearly polarized light, for the direction of propagation of this bunch polarized light is adjusted to parallel with the direction of propagation of another bunch polarized light; The described polarizer (4) is positioned in the light path of two parallel bunch polarized lights of the direction of propagation, for being adjusted to identical by the direction of vibration of two bunch polarized lights;

Optical interference circuit assembly is made up of unpolarized Amici prism (5), right-angle prism (6) and curved surface prism (7); Described unpolarized Amici prism (5) is arranged in the light path of the polarizer (4) of light source assembly, for by from the polarizer and the two bundle parallel lines polarized lights impinging perpendicularly on its surperficial non-central location are divided into two bundle reflected light and two bundle transmitted lights, described reflected light is reference light, and described transmitted light is flashlight; Described right-angle prism (6) is positioned in the light path of two bundle reference lighies, for the two bundle reference lighies entering right-angle prism are reflected back unpolarized Amici prism (5), and the reference light that the reference light that unpolarized Amici prism (5) is launched and right-angle prism are reflected back unpolarized Amici prism is not total to light path; Described curved surface prism (7) is positioned in the light path of two bundle flashlights, be reflected back unpolarized Amici prism (5) again after relative position exchange for the two bundle flashlights by entering curved surface prism, and the flashlight that unpolarized Amici prism (5) is launched is not total to light path with the flashlight being reflected back unpolarized Amici prism from curved surface prism; In unpolarized Amici prism (5), the reference light being reflected back unpolarized Amici prism from right-angle prism interferes with the flashlight being reflected back unpolarized Amici prism from curved surface prism, forms two beam interferometer light;

Signal processing component is used for receiving the two beam interferometer light launched from Amici prism (5) unpolarized in optical interference circuit assembly, and converts interference light signal to voltage signal and process, and obtains the vibration information of tested vibrating object.

2., according to claim 1 based on the heterodyne interference type vialog of laser doppler, it is characterized in that described polarization splitting prism (2), unpolarized Amici prism (5) is Single wavelength Amici prism.

3. according to claim 1 or 2 based on the heterodyne interference type vialog of laser doppler, it is characterized in that the described polarizer (4) is linear polarizer.

4. according to claim 1 or 2 based on the heterodyne interference type vialog of laser doppler, it is characterized in that described catoptron (3) is for Single wavelength deielectric-coating high reflection mirror.

5., according to claim 3 based on the heterodyne interference type vialog of laser doppler, it is characterized in that described catoptron (3) is for Single wavelength deielectric-coating high reflection mirror.

6. according to claim 1 or 2 based on the heterodyne interference type vialog of laser doppler, it is characterized in that described signal processing component comprises:

First photodetector (8) and the second photodetector (9), for receiving two beam interferometer light respectively and converting two beam interferometer light signals to voltage signal respectively;

Frequency discriminator (10), is converted into change and the output resultant voltage signal of resultant voltage amplitude for the phase differential that detects from two groups of voltage signals of the first photodetector (8) and the second photodetector (9) by the change of described phase differential;

Low-pass filter (11), for filtering from the high frequency noise in the voltage signal of frequency discriminator;

A/D converter (12), for being converted into digital signal by the analog voltage signal after filter away high frequency noise;

Computer system (13), for the process of digital signal;

Described first photodetector is connected with the input end of frequency discriminator with the output terminal of the second photodetector, the output terminal of frequency discriminator is connected with the input end of low-pass filter, the output terminal of low-pass filter is connected with the input end of A/D converter, and the output terminal of A/D converter is connected with computer system.

7., according to claim 3 based on the heterodyne interference type vialog of laser doppler, it is characterized in that described signal processing component comprises:

First photodetector (8) and the second photodetector (9), for receiving two beam interferometer light respectively and converting two beam interferometer light signals to voltage signal respectively;

Frequency discriminator (10), is converted into change and the output resultant voltage signal of resultant voltage amplitude for the phase differential that detects from two groups of voltage signals of the first photodetector (8) and the second photodetector (9) by the change of described phase differential;

Low-pass filter (11), for filtering from the high frequency noise in the voltage signal of frequency discriminator;

A/D converter (12), for being converted into digital signal by the analog voltage signal after filter away high frequency noise;

Computer system (13), for the process of digital signal;

Described first photodetector is connected with the input end of frequency discriminator with the output terminal of the second photodetector, the output terminal of frequency discriminator is connected with the input end of low-pass filter, the output terminal of low-pass filter is connected with the input end of A/D converter, and the output terminal of A/D converter is connected with computer system.

8., according to claim 4 based on the heterodyne interference type vialog of laser doppler, it is characterized in that described signal processing component comprises:

First photodetector (8) and the second photodetector (9), for receiving two beam interferometer light respectively and converting two beam interferometer light signals to voltage signal respectively;

Frequency discriminator (10), is converted into change and the output resultant voltage signal of resultant voltage amplitude for the phase differential that detects from two groups of voltage signals of the first photodetector (8) and the second photodetector (9) by the change of described phase differential;

Low-pass filter (11), for filtering from the high frequency noise in the voltage signal of frequency discriminator;

A/D converter (12), for being converted into digital signal by the analog voltage signal after filter away high frequency noise;

Computer system (13), for the process of digital signal;

Described first photodetector is connected with the input end of frequency discriminator with the output terminal of the second photodetector, the output terminal of frequency discriminator is connected with the input end of low-pass filter, the output terminal of low-pass filter is connected with the input end of A/D converter, and the output terminal of A/D converter is connected with computer system.

9., according to claim 5 based on the heterodyne interference type vialog of laser doppler, it is characterized in that described signal processing component comprises:

First photodetector (8) and the second photodetector (9), for receiving two beam interferometer light respectively and converting two beam interferometer light signals to voltage signal respectively;

Frequency discriminator (10), is converted into change and the output resultant voltage signal of resultant voltage amplitude for the phase differential that detects from two groups of voltage signals of the first photodetector (8) and the second photodetector (9) by the change of described phase differential;

Low-pass filter (11), for filtering from the high frequency noise in the voltage signal of frequency discriminator;

A/D converter (12), for being converted into digital signal by the analog voltage signal after filter away high frequency noise;

Computer system (13), for the process of digital signal;

Described first photodetector is connected with the input end of frequency discriminator with the output terminal of the second photodetector, the output terminal of frequency discriminator is connected with the input end of low-pass filter, the output terminal of low-pass filter is connected with the input end of A/D converter, and the output terminal of A/D converter is connected with computer system.