JPH0320736B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to an optical element that converts a single optical pulse into a train of optical pulses.

(Prior Art) An optical element in which two extremely flat glass plates with high reflectance surfaces facing each other and held in parallel is called a Fabry-Perot etalon or a Fabry-Perot plate.

By vertically injecting a light pulse into such an optical element, a light pulse train can be formed from a single light pulse.

FIG. 9 is a schematic diagram showing the operating principle of an optical element that uses the Fabry-Perot plate to form an optical pulse train from a single optical pulse.

The glass plates 90 and 91 are arranged in parallel, and the surfaces 90a and 9 have increased reflectance of the glass plates 90 and 91.
1a facing each other and holding them parallel,
A single optical pulse is input from the 0 side.

The light pulse that first passed through surfaces 90a and 91a with increased reflectance becomes the first pulse, and the light pulse that passed through surface 90a, reflected at surface 91a, reflected at surface 90, and transmitted through surface 91a becomes the first pulse. 2 pulses. The light that is reflected twice by surfaces 91a and 90a and transmitted through surface 91a is the third pulse, which is generated by surface 9
The light that is reflected (n-1) times by each of 1a and 90a and transmitted through the surface 91a becomes the n-th pulse.

The interval between the first pulse and the second pulse is 2l/C.

However, l is the distance between the surfaces 90a and 91a with increased reflectance, and C is the speed of light.

(Problems to be Solved by the Invention) The optical element described above can convert a single optical pulse into a train of optical pulses.

Every time the time interval of the pulse train is adjusted, it is necessary to adjust the parallelism of the two glass plates and the angle of incidence. Also, part of the incident light is reflected by the surface 91a and the surface 90
Since the components of the light that have passed through a from right to left are not used, the light utilization rate is not very large.

An object of the present invention is to provide an optical element that is easy to adjust and converts a single optical pulse into a train of optical pulses with little loss.

Still another object of the present invention is to provide an optical element for converting a single optical pulse into a train of optical pulses, which is easy to adjust, has little loss, and can further adjust the amplitude or pulse interval of the output pulse. be.

(Means for Solving the Problems) In order to achieve the above object, an optical element for converting a single optical pulse into an optical pulse train according to the present invention is configured as follows.

FIG. 1 is a block diagram showing the basic configuration of an optical element for converting a single optical pulse into an optical pulse train according to the present invention.

That is, the optical element for converting a single optical pulse into an optical pulse train according to the present invention includes an optical splitter 2 having an optical branching surface 2a, and an input means 1 for inputting a single optical pulse onto the surface of the optical branching surface 2a. , the light branching surface 2
The light pulse reflected on the surface of a and the light branching surface 2
a delay line including an optical fiber 3 that delays the light that has entered and passed through the back surface of the light branching surface 2a and makes it enter the back surface of the light branching surface 2a; It is composed of an output means 4 that outputs light that is incident and reflected from the back surface of the light branching surface 2a.

(Example) Hereinafter, the present invention will be described in more detail with reference to the drawings and the like.

FIG. 2 is a block diagram illustrating a first embodiment of an optical element for converting a single optical pulse into a train of optical pulses according to the present invention.

A single optical pulse is made incident on the surface of the optical branching surface 2a of the optical splitter 2 using a prism by an incident means for making the single optical pulse incident on the surface.

The input means consists of an optical fiber 21 and a collimator lens 25, into which a single optical pulse is input, and the single optical pulse transmitted through the optical fiber 21 is input perpendicularly to the input surface of the optical splitter 2.

The delay line including the optical fiber 23 delays the optical pulse component reflected on the surface of the optical branching surface 2a and makes it enter the back surface of the optical branching surface 2a.

A condenser lens 2 is provided on the input end face of the optical fiber 23.
6. A collimator lens 28 is provided on the output end face. The output means outputs the light that is incident on and transmitted from the front surface of the light branching surface 2a, and the light that is incident on and reflected from the back surface of the light branching surface 2a.

A condenser lens 27 is provided on the entrance surface of the optical fiber 24 forming the output means.

Next, the basic operation will be explained with reference to FIG. A light pulse with an intensity I ₀ that is emitted in parallel from the optical fiber 21 is divided into two by the light branching surface 2a of the optical splitter 2, and the first pulse with an intensity I ₁ that has passed through the optical splitter 2 is sent to the condenser lens 27. , and is emitted via the optical fiber 24.

The optical pulse reflected by the branching surface 2a of the optical splitter 2 enters the optical fiber 23 via the condensing lens 26, and the time delay due to propagation within the optical fiber 23
After t ₁ , the light enters the optical splitter 2 from the collimator lens 28 on the output end face of the optical fiber 23 . The light reflected by the light branching surface 2a is emitted from the optical fiber 24 as a second light pulse of intensity I ₂ . The light transmitted through the light branching surface 2a, incident on the optical fiber 23, and reflected on the back surface of the light branching surface 2a is emitted from the optical fiber 24 as a third light pulse having an intensity of _I3 .

In this way, a light pulse of intensity I ₀ has an intensity of
I ₁ , I ₂ , I _{3 .} . . are converted into a train of optical pulses at equal time intervals and output.

Now, let the reflectance of the light branching surface be R (<1), and the first
It is assumed that the reflectance of the optical splitter using the elements shown in the figure and FIG. 2 is the same when going from left to right in the figure and when going from bottom to top.

It is assumed that loss due to fiber coupling, loss due to optical splitter, and loss due to fiber propagation are all zero, and the optical pulse waveform is not changed by these.

I ₁ , I ₂ , I ₃ ...In is given by the following formula.

I ₁ = (1-R) I ₀ I ₂ = R ² I ₀ I ₃ = (1-R) R ² I ₀・ ・ In = (1-R) In- ₁ However, In = (1-R) In- ₁ holds true when n is 3 or more for any R.

When R is 0.5, it holds true when n is 1 or more.
That is, when R is 0.5, the amplitude of the optical pulse train is defined by a geometric series with a common ratio of 0.5.

Next, with reference to FIG. 4, the intervals of the output optical pulse train will be explained.

As shown in FIG. 4, the optical splitter 2 is formed of a cube prism, the length of each side of which is _l2 , and the refractive index is _n2 .

From the collimator lens 25 to the surface of the light splitter 2, from the collimator lens 28 to the surface of the light splitter 2, from the surface of the light splitter 2 to the condenser lens 26, and from the surface of the light splitter 2 to the condenser lens 27. Let both distances be l ₃ .

When the length of the delay line including the optical fiber 23 is l ₁ and the refractive index of the fiber is n ₁ , the interval t ₀ of the output optical pulse train is given by the following equation.

t ₀ = t ₁ + t ₂ + 2t ₃ + t ₄ However, t ₁ : n ₁ l ₁ /C t ₂ : n ₂ l ₂ /C t ₃ : n ₃ l ₃ /C (n ₃ : refractive index of air≒1 ) t ₄ : sum of time delays due to condenser lens 26 and collimator lens 28 FIG. 5 is a block diagram showing another embodiment of an optical element for converting a single optical pulse into a train of optical pulses according to the present invention.

This embodiment uses an optical fiber 21 and a collimator lens 25 forming an input means for injecting a single light pulse into the surface of the light branching surface of the embodiment shown in FIG. fiber 2
4 is removed to spatially form the input means and the output means. The basic operation is no different from the described embodiment.

FIG. 6 is a block diagram showing yet another embodiment of an optical element for converting a single optical pulse into a train of optical pulses according to the present invention.

In this embodiment, the pulse train I ₂ , I ₃ . . .
This allows the strength of In to be adjusted.

The single optical pulse reflected by the branching surface 2a of the optical splitter 2 is made incident through an ND filter 60 whose concentration is variable.

Therefore, pulses other than I ₁ are attenuated.
FIG. 7 is a block diagram showing yet another embodiment of an optical element for converting a single optical pulse into a train of optical pulses according to the present invention.

FIG. 8 is a block diagram showing an embodiment of the variable delay means of the above embodiment.

In this embodiment, the interval t ₀ of the optical pulse train explained in connection with FIG. 4 is made variable.

A light pulse is made incident on the surface of the light branching surface 2a of the light splitter 2 from an optical fiber 21 and a collimator lens 25, which are incident means for making a single light pulse incident on the surface.
The light pulse component reflected by the surface of the light branching surface 2a is made to enter the optical fiber 23 via the condenser lens 26.

A collimator lens 72 provided at the output end of the optical fiber 23 is connected to a delay adjustment means 71 as shown in FIG.

The delay amount adjusting means 71 is formed from a fixed mirror 71a and a movable mirror 71b.

By moving the movable mirror 71b left and right in the figure, the optical path length L from the output end face of the optical fiber 23 to the output end face of the optical fiber 70 can be adjusted.

The light incident on the condenser lens 73 provided at the input end of the optical fiber 70 is made incident on the optical splitter 2 via the collimator lens 28.

The optical pulse interval t ₀ of this embodiment device is determined by the formula described above.
It is obtained by replacing t ₁ in t ₀ =t ₁ +t ₂ +t ₃ +t ₄ with the following formula.

t ₁ = (n ₁ l ₁ /C) + (n ₇ l ₇ /C) + L/C + t ₈ where n ₇ : refractive index of optical fiber 70 l ₇ : length L of optical fiber 70 : output of optical fiber 23 Optical fiber 70 from the end
Distance t ₃ to the incident end of t 3 : Sum of delay times due to collimator lens 72 and condensing lens 73 As mentioned above, L can be changed by moving the movable mirror 71b left and right in the figure, so t ₀ can be made variable.

(Effects of the Invention) As explained in detail above, the optical element for converting a single optical pulse into an optical pulse train according to the present invention includes an optical splitter having an optical branching surface, and a single optical pulse on the surface of the optical branching surface. a delay including an input means for inputting the light, and an optical fiber that delays the light pulse reflected on the surface of the light branching surface and the light that is incident and transmitted from the back surface of the light branching surface and causes the light to enter the back surface of the light branching surface. It is composed of a line and an output means for outputting light that is incident on and transmitted from the front surface of the light branching surface and light that is incident and reflected from the back surface of the light branching surface.

Therefore, a single optical pulse can be effectively distributed to create a train of optical pulses that decays at a constant rate at equal time intervals.

And it can perform conversion with less loss than an optical element that uses a Fabry-Perot plate to form an optical pulse train from a single optical pulse.

In conventional optical elements, as mentioned above, there are always components that cannot be used. However, in the element according to the present invention, if there is no loss due to optical axis deviation and pulses up to the ∞th pulse are used, the utilization factor becomes 1.

Fabry-Perot obtained a pulse interval of 80 ps to 1 ns using glass plates with a spacing of 1.2 cm to 15 cm.
As a result, if the distance is large, it becomes difficult to adjust the parallelism.

In the example of the optical element according to the present invention, it was possible to obtain continuous pulses with a pulse interval of 1 ns or more by performing the delay using an optical fiber whose length is easily 20 cm or more. In addition, since it goes back and forth between the glass plates, the optical path is estimated to be twice as large, and the refractive index n of the optical fiber is set to 1.5, and the delay is calculated as that in vacuum (or air).
The estimate was 1.5 times higher.

This optical element can be used for time axis calibration of streak cameras, etc.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing the basic configuration of an optical element for converting a single optical pulse into a train of optical pulses according to the present invention. FIG. 2 is a block diagram illustrating a first embodiment of an optical element for converting a single optical pulse into a train of optical pulses according to the present invention. FIG. 3 is a schematic diagram for explaining the relationship between the input and output intensities of an optical element that converts a single optical pulse into a train of optical pulses according to the present invention. FIG. 4 is an enlarged block diagram showing the vicinity of the optical branching section of the first embodiment.
FIG. 5 is a block diagram illustrating a second embodiment of an optical element for converting a single optical pulse into a train of optical pulses according to the present invention. FIG. 6 is a block diagram showing a third embodiment of an optical element for converting a single optical pulse into a train of optical pulses according to the present invention. FIG. 7 is a block diagram showing a fourth embodiment of an optical element for converting a single optical pulse into a train of optical pulses according to the present invention. FIG. 8 is a block diagram showing an embodiment of the variable delay means of the fourth embodiment. FIG. 9 is a schematic diagram showing the operating principle of an optical element that uses the Fabry-Perot plate to form an optical pulse train from a single optical pulse. 1... Input means, 2... Optical splitter, 3... Optical fiber, 4... Output means, 21... Optical fiber forming input means, 24... Optical fiber forming output means, 23, 70... Forming delay line. Optical fiber, 25, 28, 72...Collimator lens, 2
6, 27, 73...Condenser lens, 60...ND filter, 71...Delay amount adjustment means.

Claims (1)

[Scope of Claims] 1. An optical branching device having a light branching surface, an input means for inputting a single light pulse onto the surface of the light branching surface, and a light pulse reflected on the surface of the light branching surface and the light beam. a delay line including an optical fiber that delays the light that has entered and passed through the back surface of the light branching surface and makes it enter the back surface of the light branching surface; and the light that has entered and passed through the front surface of the light branching surface and the light branching surface. An optical element that converts a single optical pulse into an optical pulse train, and includes an output means that outputs light that is incident on the back surface of the optical system and reflected. 2. The input means is an optical fiber having a single optical pulse connected to one end and a collimator lens provided at the other end, and inputting the single optical pulse as parallel light into the optical splitter. An optical element that converts a single optical pulse according to item 1 into a train of optical pulses. 3. Converting a single optical pulse into an optical pulse train according to claim 1, wherein the optical fiber forming the delay line is provided with a condensing lens on its entrance surface and a collimator lens on its exit surface. optical element. 4. An optical element for converting a single optical pulse into an optical pulse train according to claim 1, wherein the output means is an optical fiber having a condenser lens provided on a surface opposite to the output surface of the optical splitter. . 5. An optical branching device having an optical branching surface, an input means for inputting a single optical pulse onto the surface of the optical dividing surface, and an optical pulse reflected on the surface of the optical dividing surface and inputting from the back surface of the optical dividing surface. a delay line including an optical fiber that delays the transmitted light and causes it to enter the back surface of the optical branching surface; and an intensity adjustment means that adjusts the intensity of the light that is returned to the optical splitter via the delay line. An optical element that converts a single optical pulse into an optical pulse train, and includes an output unit that outputs light that is incident on and transmitted from the front surface of the optical branching surface and light that is incident and reflected from the back surface of the optical branching surface. 6 an optical splitter having an optical branching surface; an input means for inputting a single optical pulse onto the surface of the optical branching surface; a delay line including an optical fiber that delays the transmitted light and causes it to enter the back surface of the optical branching surface; and a delay amount adjusting means that adjusts the amount of delay of the light that is returned to the optical splitter via the delay line. and an optical element for converting a single optical pulse into an optical pulse train, comprising an output means for outputting light that is incident on and transmitted from the front surface of the optical branching surface and light that is incident and reflected from the back surface of the optical branching surface.