CN110441034A - Optical device attenuation characteristic test device and method based on Mach-Zehnder interferometer - Google Patents

Abstract

Optical device attenuation characteristic test device and method based on Mach-Zehnder interferometer, device include first light source, 1/2 wave plate, Brewster window, beam splitter, reflecting mirror, detector, second light source, Glan prism and processing system；By being inserted into optical device to be tested on the one arm of Mach-Zehnder interferometer, the phase change of laser irradiation is measured, the refractive index of optical device is obtained；On optical device under test plus RGB laser is as test light, and the Output optical power of optical device under test is detected by detector, obtains the variation of optical device amplitude, changes available accurate attenuation characteristic using phase change and amplitude.

Description

Optical device attenuation characteristic test device and method based on Mach-Zehnder interferometer

Technical field

The invention belongs to optical material attenuation measurement fields, specifically, the present invention provides one kind to be based on Mach Zeng Degan The optical device attenuation characteristic test device and method of interferometer.

Background technique

In laser display technology, optical device laser -induced damage problem is limit Laser energy transmission efficiency one big Bottleneck, optical device by the irradiation of laser beam, cause optical device lattice structure that defect occurs, lead to optical device for a long time The optical characteristics such as absorption coefficient, refractive index change, the laser delivery efficiency decline of optical device.Therefore, Study of Laser irradiates The attenuation characteristic of lower optical device helps to improve optical device progress performance.

In the method for existing optical device attenuation characteristic measurement, has and device for non-linear optical is carried out using laser freuqency doubling The patent of damage and damage detection has considerable restraint to the optical device that can be tested, and system constitutes complexity, tests environment It is required that it is high, it is expensive；In addition there is the optical device damage check for LED light source, but what is predominantly detected is optical device The defects of external microlesion.And it is more single currently for the test method of optical device laser -induced damage, it can only measure Single optical parameter lacks the test method and device of optical device attenuation characteristic under complete evaluation laser irradiation comprehensively.

Summary of the invention

In view of the problems of the existing technology, the present invention provides a kind of optical devices based on Mach-Zehnder interferometer to decline Subtract characteristic test device and method, by being inserted into optical device to be tested on the one arm of Mach-Zehnder interferometer, measures The phase change of laser irradiation obtains the refractive index of optical device；On optical device under test plus RGB laser is as test Light is detected the Output optical power of optical device under test by detector, obtains the variation of optical device amplitude, utilize phase change Change available accurate attenuation characteristic with amplitude.

Optical device attenuation characteristic test device based on Mach-Zehnder interferometer, including first light source, 1/2 wave plate, cloth Scholar this special window, beam splitter, reflecting mirror, detector, second light source, Glan prism and processing system；Wherein:

Mach-Zehnder interferometer part: first light source exit end sequence places 1/2 wave plate and Brewster window, after Brewster window Place the first beam splitter, light beam is divided into two-way after the first beam splitter, curb original direction transmission, another way perpendicular to Former direction；It constitutes Mach-Zehnder interferometer two-arm: the first reflecting mirror being added in all the way, makes beam propagation side at 45 degree of angles with light beam Change to 90 degree of generation, which is reference arm；The second reflecting mirror is added in another way in the same way, the light beam after reflection according to It is secondary to pass through the first Glan prism and the second Glan prism；The second combiner device is placed in two-way light intersection, the light quilt after closing beam First detector receives, and enters processing system afterwards.

Optical system for testing part: second light source emergent light passes through third beam splitter, and the light along the transmission of former direction is visited by second Device is surveyed to receive；Pass through above-mentioned first Glan prism respectively perpendicular to the light of former direction transmission, when then passing through the second Glan prism 90 degree of variations occur for beam Propagation direction, are received by third detector；Second, third detector accesses processing system.

The first light source, using narrow linewidth laser, for providing coherent light signal；

1/2 wave plate and Brewster window combination, for coherent light signal to be polarized, make its polarization state and second light source It is vertical to be emitted polarization state；

Described first, the light that third beam splitter is used to for incident light being divided into two beam isocandelas is emitted, and the second combiner device is used for Two beam incident lights are combined into light beam outgoing；

The reflecting mirror, for changing the transmission direction of light；

The detector, for received optical signal to be converted to electric signal；

The light source of any required test can be used in the second light source；

The Glan prism is emitted for incident light to be divided into two bundles orthogonal linearly polarized light；

The processing system handles acquisition signal, finally obtains amplitude and phase information.

Optical device attenuation characteristic test method based on Mach-Zehnder interferometer, this method the specific implementation process is as follows:

1, adjustment Mach-Zehnder interferometer makes it to generate clearly interference fringe；

2, system source, that is, first light source is opened, observes and records interference pattern at the first optical detector；

3, first light source is closed, testing light source, that is, second light source is opened, records second light source power with second and third detector；

4, second light source is closed, optical device under test is placed between two Glan prisms；

5, the first, second light source, the power that the second third detector of record receives are opened, while recording the first detector and receiving The interference pattern arrived；

6, it is handled by computer, obtains the decaying of laser irradiation optical device generation.

One aspect of the present invention is another by the phase change using Mach-Zehnder interferometer measurement laser irradiation optical device Aspect is changed by the amplitude of laser irradiation optical device, is calculated the complex refractivity index of laser irradiation optical device, is completely commented Valence goes out optical device laser -induced damage.The system structure that the invention is related to is simple and stablizes, and multi-parameter is automatic, and error is smaller.

Detailed description of the invention

Fig. 1 is optical element attenuation characteristic optical system for testing schematic diagram.

Specific embodiment

In conjunction with Fig. 1, to based on Mach-Zehnder interferometer optical device attenuation characteristic test device and method carry out it is detailed Description.

The test device includes Mach-Zehnder interferometer, optical device under test, Glan prism, beam splitter, test light Source and corresponding detector.

The Mach-Zehnder interferometer scheme isometric using two-arm.

The Mach-Zehnder interferometer is using He-Ne laser as system source.

The combination of one of plus thirty wave plate and Brewster window after the light source, for by the polarization direction of He-Ne laser It is adjusted to orthogonal with second light source polarization direction.

The beam splitter uses half-silvered mirror.

The second light source preferably uses redgreenblue laser.

The conjunction beam and beam splitting of test light and system light are all made of Glan devating prism, will be inclined using its polarization spectro principle The orthogonal two-beam in direction that shakes closes beam and beam splitting.

The interference fringe detector of the Mach-Zehnder interferometer is ccd detector.

The testing light source selects redgreenblue laser respectively.It can according to need and carry out red green combination, red Lan Zuhe, Bluish-green combination and redgreenblue combination, and when being tested using combined light source, attempt different color proportions.

First detector is ccd detector, for receiving interference pattern；

Second, third described detector is photodetector, is used for received optical power；

Based on optical device under test, refractive index in the case where laser irradiation can change and with declining to light this programme Subtract, the variations in refractive index of optical device under test can be accurately acquired by the variation of the interference fringe of Mach-Zehnder interferometer, And added test light is the refractive index of optical device and the function of decaying in the transmitance of optical device under test, is obtained using detector To the input-output power of test light, and then can solve to obtain the attenuation characteristic of optical device under test.Its basic principle is as follows:

According to the absorption of light in wave optics, when laser irradiation is added on optical device, the part energy of light wave in communication process Amount is absorbed and converted to the energy of other forms, causes the decaying of light.When considering the absorption loss of light, complex refractivity index is defined N:

Real part n, commonly referred to as medium refraction index, and imaginary part K is known as extinction coefficient, indicates the loss of light.

When light wave normal incidence is to optical device, transmission coefficient at this time is

WhereinFor air refraction.So transmissivity is

And transmitance can be obtained by the detector in optical system for testing:

WhereinThe optical power received for input power known to optical system for testing, i.e. the second detector；For optical system for testing The optical power that the Output optical power that middle detector detects, i.e. third detector receive.

The medium refraction index variation for measuring optical device under test is realized by the interference fringe in interferometer.It is being not added When optical device under test, with the interference fringe of the first detector record at this time；Optical device under test is put into wherein, is added first Light source, as test light, the mobile number of interference fringe at this time is recorded by the first detector as system light and second light source, Assuming that mobile number is N, then at this time optical path difference relatively before knots modification beFor the wavelength interfered, then have

Wherein d is optical device under test along optical transport The length in direction.Pass through the refractive index of the available optical device under test of (5) formula during laser irradiation

(6) formula is substituted into the available extinction coefficient K of (3) (4) formula

Finally byThe absorption coefficient of optical device is calculated, whereinFor the propagation constant in vacuum.

Steps are as follows for a kind of optical device attenuation characteristic test method based on Mach-Zehnder interferometer:

1, Mach-Zehnder interferometer is adjusted, two-arm equal length is kept, opens He-Ne laser, it is clear high right to be allowed to generate Than the interference fringe of degree, record is received with detector D1, that is, ccd detector；

2, He-Ne laser is closed, the RGB laser light source of optical system for testing is opened, in power meter D2 and D3 record optical system for testing Two Glan prism bring fixed loss；

3, optical device under test is put into signal arm, adjustment optical device under test position makes laser pass through its center；

4, He-Ne laser and RGB laser are opened, the mobile feelings of recording interference fringe are received with detector D1, that is, ccd detector Condition；Light power meter D2 and D3 are opened simultaneously, incident light and the emergent light after optical device under test are received；

5, ccd detector pass through A/D converter, be linked into computer with light power meter D2 and D3, according to theoretical calculation go out to Phase change and the amplitude variation that photometry device introduces, and then its variations in refractive index and attenuation coefficient are obtained, realize optics device The measurement of part attenuation characteristic.

Note: since this technology is most commonly used in laser display, and the light source of laser display is red green blue tricolor laser, because This when being tested using this device and method, testing light source select redgreenblue laser, while can according to need into The red green combination of row, red Lan Zuhe, bluish-green combination and redgreenblue combination, and when being tested using combined light source, it attempts not Same color proportion.

Claims (9)

1. the optical device attenuation characteristic test device based on Mach-Zehnder interferometer, it is characterised in that: including first light source, 1/ 2 wave plates, Brewster window, beam splitter, reflecting mirror, detector, second light source, Glan prism and processing system；Wherein:

Mach-Zehnder interferometer part: first light source exit end sequence places 1/2 wave plate and Brewster window, after Brewster window Place the first beam splitter, light beam is divided into two-way after the first beam splitter, curb original direction transmission, another way perpendicular to Former direction；It constitutes Mach-Zehnder interferometer two-arm: the first reflecting mirror being added in all the way, makes beam propagation side at 45 degree of angles with light beam Change to 90 degree of generation, which is reference arm；The second reflecting mirror is added in another way in the same way, the light beam after reflection according to It is secondary to pass through the first Glan prism and the second Glan prism；The second combiner device is placed in two-way light intersection, the light quilt after closing beam First detector receives, and enters processing system afterwards；

Optical system for testing part: second light source emergent light passes through third beam splitter, and the light along the transmission of former direction is by the second detector It receives；Pass through above-mentioned first Glan prism, light beam when then passing through the second Glan prism respectively perpendicular to the light of former direction transmission 90 degree of variations occur for transmission direction, are received by third detector；Second, third detector accesses processing system.

2. the optical device attenuation characteristic test device based on Mach-Zehnder interferometer, feature exist according to claim 1 In: the first light source, using narrow linewidth laser, for providing coherent light signal.

3. the optical device attenuation characteristic test device based on Mach-Zehnder interferometer, feature exist according to claim 1 In: 1/2 wave plate and Brewster window combination for coherent light signal to be polarized, make its polarization state and second light source It is vertical to be emitted polarization state.

4. the optical device attenuation characteristic test device based on Mach-Zehnder interferometer, feature exist according to claim 1 In: first, second Glan prism, for incident light to be divided into two bundles to orthogonal linearly polarized light, it is therefore intended that the first light Source is separated with second light source.

5. the optical device attenuation characteristic test device based on Mach-Zehnder interferometer, feature exist according to claim 1 In: described first, the light that third beam splitter is used to for incident light being divided into two beam isocandelas is emitted, and the second combiner device is used for will Two beam incident lights are combined into light beam outgoing.

6. the optical device attenuation characteristic test device based on Mach-Zehnder interferometer, feature exist according to claim 1 In: the detector, for received optical signal to be converted to electric signal.

7. the optical device attenuation characteristic test device based on Mach-Zehnder interferometer, feature exist according to claim 1 In: the second light source, using the light source of any need test.

8. the optical device attenuation characteristic test device based on Mach-Zehnder interferometer, feature exist according to claim 1 In: the processing system handles acquisition signal, finally obtains amplitude and phase information.

9. the optical device attenuation characteristic test method based on Mach-Zehnder interferometer, it is characterised in that: specific implementation process is such as Under:

1, adjustment Mach-Zehnder interferometer makes it to generate clearly interference fringe；

2, system source, that is, first light source is opened, observes and records interference pattern at the first optical detector；

3, first light source is closed, testing light source, that is, second light source is opened, records second light source power with second and third detector；

4, second light source is closed, optical device under test is placed between two Glan prisms；

5, the first, second light source, the power that the second third detector of record receives are opened, while recording the first detector and receiving The interference pattern arrived；

6, it is handled by computer, obtains the decaying of laser irradiation optical device generation.