CN201378236Y - System producing cylindrical vector light beams by utilizing computed hologram - Google Patents

Abstract

The utility model relates to a system producing cylindrical vector light beams by utilizing computed hologram. The light beams generated by a common mono-mode laser are taken as input light and form parallel light beams through a beam expanding shaper; then parallel light beams pass through a computed hologram sheet, a Fourier transform lens, a spatial filter and a Fourier inverse transform lens, thereby forming laser TEM[10] (or TEM[01]) model light beams; the optical axis is changed through a refracting prism; linearly polarized light with a certain angle is formed through a polarizer; and a proper amount of light beams are synthesized through a Mach-Zehnder interferometer. The utility model has the advantages of low requirement on incidence light beams, simple device, easy operation, high polarization degree of output cylindrical vector, and the like.

Description

Utilize calculation holographic to produce the system of column vector beam

Technical field

The utility model relates to a kind of optical technical field, particularly a kind of system that utilizes calculation holographic to produce column vector beam.

Background technology

Radial polarisation light (Radial polarized beams) and position angle polarized light (azimuthalpolarized beams) are called column vector beam (Cylindrical polarized beams), and they have the symmetry of height.Since some characteristics of column vector beam may be used on the imprison of particle speed technology, optical tweezers, materials processing, particulate and control, fields such as large-numerical aperture lens and some special measuring methods.For example, column vector beam can be applicable to realize the super-resolution effect in the optical microscope system, because certain column vector beam is littler than the horizontal hot spot of the focus of linearly polarized light beam focusing in the same focusing system through focusing on back focus.The generation system of column vector beam is research and the indispensable precondition of utilizing circulation polarized light beam, has caused extensive concern.Produce column vector beam a variety of methods are arranged, such as, adjust the crystal of a branch of linearly polarized light by the nematic phase distortion of its directive aligned twisted, synthetic with the linearly polarized light that two bundle polarization directions are mutually orthogonal by interferometer, interfering after the phase place of modulated beam of light diverse location and synthesize, is exactly to utilize the method for interferometer and diffraction that the laser-based transverse mode is changed or the like simultaneously in addition.Every kind of method has superiority, and still, still exists some essence not enough, mainly is incident light requirement height and the column vector beam that can't produce high-polarization.

For the selection of zlasing mode, what common laser instrument was exported is that the fundamental transverse mode light beam (is designated as TEM ₀₀Mould).But, synthesize column vector beam, must use TEM ₁₀(or TEM ₀₁) the mould light beam.Like this, will change the output mode of laser instrument.By Principles of Laser as can be known, it promptly is to select fundamental transverse mode in a large amount of transverse modes that participate in vibration that common transverse mode is selected, greater than fundamental transverse mode, suppress its vibration according to the occupied space of high-order transverse mode thereby therefore in resonator cavity, add the diaphragm of certain size restriction and the chamber type of appropriate design resonator cavity and the diffraction loss that parameter will increase the high-order transverse mode.The method of selecting can be divided two kinds, and the first realizes the fundamental transverse mode running by the geometry and the chamber parameter of design resonator cavity, and it two is to add the modeling element in the chamber.Yet, keep TEM ₁₀(or TEM ₀₁) mould light beam and to suppress the mould on other rank will be more complicated, and the resonator cavity that changes laser also is cumbersome, such as, can design an annulus that has a line by the center of circle, can realize exporting TEM preferably in theory ₁₀(or TEM ₀₁) the mould light beam, yet very high for the accuracy requirement of intermediate filtered line, so be difficult in the reality realize.Along with developing rapidly of information society and kownledge economy, each rank pattern of laser is in various experiments and use more and more widely in manufacturing and designing, and seems more important in national defense construction and modern science and technology.The zlasing mode of therefore, can be simply, obtaining institute's palpus quickly is very crucial.

Summary of the invention

The utility model is that the method incident light at present realization column vector beam requires height, realizes the problem of difficulty, has proposed a kind of system that utilizes calculation holographic to produce column vector beam, utilizes the undistorted characteristic of calculation holographic, realizes laser TEM ₁₀(or TEM ₀₁) the mould light beam, finally obtain column vector beam, the degree of polarization height of the column vector beam that the method is low to the incident light requirement, adjusted simple, produce.

The technical solution of the utility model is: a kind of system that utilizes calculation holographic to produce column vector beam, comprise single-mode laser 1, lens 2, circular hole diaphragm 3, lens 4, hologram sheet 5, Fourier transform lens 6, spatial filter 7, inverse Fourier transform lens 8, refracting prisms 9, the polarizer 10, beam-splitter 11, reflecting prism 12, phase-plate 14, plane mirror 15, polarization closes light microscopic 16, single-mode laser 1 output fundamental transverse mode light beam, forming directional light through the expansion bundle reshaper of forming by lens 2 and lens 4, expand in the bundle reshaper and place a circular hole diaphragm 3, directional light symmetry optical axis vertical incidence hologram sheet 5; Light beam obtains TEM through Fourier transform lens 6 backs on the back focal plane of Fourier transform lens 6 ₁₀Or TEM ₀₁The Fourier transform frequency spectrum of mould light beam; A spatial filter 7 is arranged on the back focal plane of Fourier transform lens 6, allow the required order of diffraction time pass through; Behind the light beam process inverse Fourier transform lens 8, obtain TEM ₁₀Or TEM ₀₁The mould light beam; TEM ₁₀Or TEM ₀₁The mould light beam changes the direction of propagation through refracting prisms 9; Pass through the polarizer 10 again; Through becoming the aplanatic light beam of two bundles behind the beam-splitter 11 that simultaneously scribbles semi-transparent semi-reflecting film; A branch of light becomes TEM through image rotation reflecting prism 12 ₀₁Or TEM ₁₀The mould light beam also changes optical axis direction; Another Shu Guang passes through the plane mirror of placing into 45 degree 15 and changes optical axis direction through variable phase plate 14; Two-beam closes light microscopic 16 coherence stack at polarization, from other end output column vector beam.

Described hologram sheet is to obtain with calculating the holographic method of picture, comprises sampling to thing light wave mathematic(al) representation, is encoded to transmittance function, draws and reduction with computing machine.

Described expansion bundle reshaper is Kepler's type beam expanding lens.

Described Fourier transform lens 6 and inverse Fourier transform lens 8 are positive lens, and the focal length of Fourier transform lens 6 is more than or equal to the focal length of inverse Fourier transform lens 8.

The front focus of described inverse Fourier transform lens 8 overlaps with the back focus of Fourier transform lens 6.

Described spatial filter 7 is positioned at the front focal plane of inverse Fourier transform lens 8.

Described a branch of light becomes TEM through image rotation reflecting prism 12 ₀₁Or TEM ₁₀The mould light beam can select to add 1/2 wave plate 13 according to required post vector light beam before entering polarization to close light microscopic 16.

The beneficial effects of the utility model are: the utility model utilizes calculation holographic to produce the system of column vector beam, unrestricted to the polarization state of incident beam, for incident beam require low, the system applies scope is wide, the degree of polarization height of the column vector beam of generation.

Description of drawings

Fig. 1 calculates the image plane holographic process flow diagram for the utility model utilizes calculation holographic to produce in the system of column vector beam;

Fig. 2 produces synthetic post schematic vector diagram in the system of column vector beam for the utility model utilizes calculation holographic;

Fig. 3 produces the system architecture synoptic diagram of column vector beam for the utility model utilizes calculation holographic.

Embodiment

Fig. 1 is for calculating the image plane holographic process flow diagram, comprises sampling to thing light wave mathematic(al) representation, is encoded to transmittance function, draws and reduction with computing machine, and concrete steps are as follows: to laser TEM ₁₀(or TEM ₀₁) sampling of mould expression formula, expression formula is

$E_{01}(x,y,z)=A_{01}{E}_0\frac{{\mathrm{\&omega;}}_{0}y}{{\mathrm{\&omega;}}^2\left(z\right)}\exp [-\frac{x^2+{\mathrm{<figure-callout\; id="2"\; label="y"\; filenames="Y2009200672600010H3.png"\; state="\{\{state\}\}">y</figure-callout>}}^2}{{\mathrm{\&omega;}}^2\left(z\right)}-i{\mathrm{\&Phi;}}_{01}(x,y,x)]$

$E_{10}(x,y,z)=A_{10}{E}_0\frac{{\mathrm{\&omega;}}_{0}x}{x^2\left(z\right)}\exp [-\frac{x^2+{\mathrm{<figure-callout\; id="2"\; label="y"\; filenames="Y2009200672600010H3.png"\; state="\{\{state\}\}">y</figure-callout>}}^2}{{\mathrm{\&omega;}}^2\left(z\right)}-{\mathrm{i\&Phi;}}_{10}(x,y,x)]$

In the formula:

$\mathrm{\&omega;}\left(a\right)={\mathrm{\&omega;}}_0\sqrt{1+{\left(\frac{z}{f}\right)}^2}=\sqrt{\frac{\mathrm{L\&lambda;}}{2\mathrm{\&pi;}}[1+{\left(\frac{z}{f}\right)}^2]}$

${\mathrm{\&Phi;}}_{01}(x,y,z)={\mathrm{\&Phi;}}_{10}(x,y,z)=k[f+z+\frac{z(x^2+y^2)}{2({\mathrm{<figure-callout\; id="2"\; label="f"\; filenames="Y2009200672600010H3.png"\; state="\{\{state\}\}">f</figure-callout>}}^2+z^2)}]-2(\frac{\mathrm{\&pi;}}{4}+\arctan \frac{z}{f})$

In the following formula, A _MnBe normaliztion constant; L is that confocal resonator is long; $f=\frac{\mathrm{<figure-callout\; id="2"\; label="R"\; filenames="Y2009200672600010H3.png"\; state="\{\{state\}\}">R</figure-callout>}}{2}=\frac{\mathrm{<figure-callout\; id="2"\; label="L"\; filenames="Y2009200672600010H3.png"\; state="\{\{state\}\}">L</figure-callout>}}{2}$ Focal length for the chamber mirror.With two-dimensional comb function as sampling function, function f (x, sampling y) is defined by following formula:

$f_s(x,y)=f(x,y)\mathrm{comb}(\frac{x}{X},\frac{y}{Y})$

Wherein

$\mathrm{comb}(\frac{x}{X},\frac{y}{Y})=\mathrm{XY}\underset{m=-\&infin;}{\overset{\&infin;}{\mathrm{\&Sigma;}}}\underset{n=-\&infin;}{\overset{\&infin;}{\mathrm{\&Sigma;}}}\mathrm{\&delta;}(x-\mathrm{mX},y-\mathrm{nY})$

Therefore, sample value function f _s(x y) is made up of the array of δ function, and the width of space on the x direction between each δ function is X, and the width on the y direction is Y; Adopt circuitous phase method coding; After in computing machine, finishing amplitude and phase encoding, available computers control plotting apparatus, output is plotted on the paper or exposes on sensitive film.Miniature with accurate camera again to suitable dimension (about 5 millimeters square).

Fig. 2 is synthetic post schematic vector diagram, and arrow is represented the polarization state direction, and the available polarizer is selected.Its principle is: utilize laser TEM ₀₁And TEM ₁₀The mould light beam can synthesize column vector beam, and establishing two input light is same-phase,

$E_{\left(x\right)}(r,\mathrm{\&theta;})=E_0\sqrt{\mathrm{\&rho;}}\exp (-\mathrm{\&rho;}/2)\cos \left(\mathrm{\&theta;}\right),$

$E_{\left(y\right)}(r,\mathrm{\&theta;})=E_0\sqrt{\mathrm{\&rho;}}\exp (-\mathrm{\&rho;}/2)\sin \left(\mathrm{\&theta;}\right)$

In the formula, r and θ represent polar coordinate system, E ₀Be amplitude, w is a waist of Gaussian beam spot radius, ρ=2r ²/ w ²Carrying out simple vector addition subtracts:

$E_{\left(\mathrm{\&theta;}\right)}(r,\mathrm{\&theta;})=\hat{y}{E}_{\left(x\right)}(r,\mathrm{\&theta;})-\hat{x}{E}_{\left(y\right)}(r,\mathrm{\&theta;})=\widehat{\mathrm{\&theta;}}{E}_0\sqrt{\mathrm{\&rho;}}\exp (-\mathrm{\&rho;}/2),---\left(1\right)$

$E_{\left(r\right)}(r,\mathrm{\&theta;})=\hat{x}{E}_{\left(x\right)}(r,\mathrm{\&theta;})+\hat{y}{E}_{\left(y\right)}(r,\mathrm{\&theta;})=\hat{r}{E}_0\sqrt{\mathrm{\&rho;}}\exp (-\mathrm{\&rho;}/2),---\left(2\right)$

In the formula

With

Be position angle and unit vector radially, its Chinese style (1) is represented position angle polarized light and radial polarisation light respectively with formula (2).

Fig. 3 utilizes calculation holographic to produce the device structure synoptic diagram of column vector beam, comprise single-mode laser 1, lens 2, circular hole diaphragm 3, lens 4, hologram sheet 5, Fourier transform lens 6, spatial filter 7, inverse Fourier transform lens 8, refracting prisms 9, the polarizer 10, beam-splitter 11, reflecting prism 12,1/2 wave plate 13, phase-plate 14, plane mirror 15, its concrete course of work is: single-mode laser 1 output fundamental transverse mode light beam; Lens 2 are formed expansion bundle reshaper with lens 4, are Kepler's type beam expanding lens; Expand in the bundle reshaper and place a circular hole diaphragm 3, purpose is to filter out on the xsect decentering point light of certain distance apart, in order to carry the light filtering accuracy, the diaphragm out of focus is placed; Input light is forming directional light, symmetrical optical axis vertical incidence hologram sheet 5 through expanding the bundle reshaper; Light beam obtains TEM through Fourier transform lens 6 backs on the back focal plane of Fourier transform lens 6 ₁₀(or TEM ₀₁) the Fourier transform frequency spectrum of mould light beam; On the back focal plane of Fourier transform lens 6, place a spatial filter 7, allow the required order of diffraction time pass through; Behind the light beam process inverse Fourier transform lens 8, obtain required plural object wave face, promptly needed TEM ₁₀(or TEM ₀₁) the mould light beam; TEM ₁₀(or TEM ₀₁) the mould light beam process refracting prisms 9 change directions of propagation; Pass through the polarizer 10 again; Through becoming the aplanatic light beam of two bundles behind the beam-splitter 11 that simultaneously scribbles semi-transparent semi-reflecting film; A branch of light becomes TEM through image rotation reflecting prism 12 ₀₁(or TEM ₁₀) mould light beam and change optical axis direction, select to add 1/2 wave plate 13 according to required post vector light beam; Another Shu Guang passes through the plane mirror of placing into 45 degree 15 and changes optical axis direction through variable phase plate 14; Two-beam closes light microscopic 16 coherence stack at polarization, from other end output column vector beam.

Described hologram sheet is for obtaining with calculating the holographic method of picture; Described Fourier transform lens 6 and inverse Fourier transform lens 8 are positive lens, and the focal length of Fourier transform lens 6 is more than or equal to the focal length of inverse Fourier transform lens 8; The front focus of described inverse Fourier transform lens 8 overlaps with the back focus of Fourier transform lens 6; Described spatial filter 7 is positioned at the front focal plane of inverse Fourier transform lens 8; Phase-plate 14 in the described Mach-Zehnder interferometer is variable phase plates, and plate and control phase plate use by way of compensation; Must add the polarizer 10 before the described Mach-Zehnder interferometer.

Claims (6)

1, a kind of system that utilizes calculation holographic to produce column vector beam, it is characterized in that, comprise single-mode laser (1), lens (2), circular hole diaphragm (3), lens (4), hologram sheet (5), Fourier transform lens (6), spatial filter (7), inverse Fourier transform lens (8), refracting prisms (9), the polarizer (10), beam-splitter (11), reflecting prism (12), phase-plate (14), plane mirror (15), polarization closes light microscopic (16), single-mode laser (1) output fundamental transverse mode light beam, forming directional light through the expansion bundle reshaper of forming by lens (2) and lens (4), expand in the bundle reshaper and place a circular hole diaphragm (3), directional light symmetry optical axis vertical incidence hologram sheet (5); Light beam obtains TEM through Fourier transform lens (6) back on the back focal plane of Fourier transform lens (6) ₁₀Or TEM ₀₁The Fourier transform frequency spectrum of mould light beam; A spatial filter (7) is arranged on the back focal plane of Fourier transform lens (6), allow the required order of diffraction time pass through; Behind the light beam process inverse Fourier transform lens (8), obtain TEM ₁₀Or TEM ₀₁The mould light beam; TEM ₁₀Or TEM ₀₁The mould light beam changes the direction of propagation through refracting prisms (9); Pass through the polarizer (10) again; Through becoming the aplanatic light beam of two bundles behind the beam-splitter (11) that simultaneously scribbles semi-transparent semi-reflecting film; A branch of light becomes TEM through image rotation reflecting prism (12) ₀₁Or TEM ₁₀The mould light beam also changes optical axis direction; Another Shu Guang passes through the plane mirror of placing into 45 degree (15) and changes optical axis direction through variable phase plate (14); Two-beam closes light microscopic (16) coherence stack at polarization, from other end output column vector beam.

2, according to the described system that utilizes calculation holographic to produce column vector beam of claim 1, it is characterized in that described expansion bundle reshaper is Kepler's type beam expanding lens.

3, according to the described system that utilizes calculation holographic to produce column vector beam of claim 1, it is characterized in that, described Fourier transform lens (6) and inverse Fourier transform lens (8) are positive lens, and the focal length of Fourier transform lens (6) is more than or equal to the focal length of inverse Fourier transform lens (8).

4, according to the described system that utilizes calculation holographic to produce column vector beam of claim 1, it is characterized in that the front focus of described inverse Fourier transform lens (8) overlaps with the back focus of Fourier transform lens (6).

5, according to the described system that utilizes calculation holographic to produce column vector beam of claim 1, it is characterized in that described spatial filter (7) is positioned at the front focal plane of inverse Fourier transform lens (8).

According to the described system that utilizes calculation holographic to produce column vector beam of claim 1, it is characterized in that 6, described a branch of light becomes TEM through image rotation reflecting prism (12) ₀₁Or TEM ₁₀The mould light beam closes that light microscopic (16) is preceding can select add 1/2 wave plate (13) according to required post vector light beam entering polarization.

Images