U.S. patent application number 14/022129 was filed with the patent office on 2015-03-12 for multi-stage mopa with first-pulse suppression.
This patent application is currently assigned to COHERENT KAISERSLAUTERN GMBH. The applicant listed for this patent is COHERENT KAISERSLAUTERN GMBH. Invention is credited to Ralf KNAPPE, Albert SEIFERT, Alexander Weis.
Application Number | 20150070753 14/022129 |
Document ID | / |
Family ID | 52625346 |
Filed Date | 2015-03-12 |
United States Patent
Application |
20150070753 |
Kind Code |
A1 |
KNAPPE; Ralf ; et
al. |
March 12, 2015 |
MULTI-STAGE MOPA WITH FIRST-PULSE SUPPRESSION
Abstract
A solid-state MOPA includes a mode-locked laser delivering a
train of pulses. The pulses are input to a fast E-O shutter,
including polarization-rotating elements, polarizing
beam-splitters, and a Pockels cell that can be driven alternatively
by high voltage (HV) pulses of fixed long and short durations. A
multi-pass amplifier follows the E-O shutter. The E-O shutter
selects every Nth pulse from the input train and delivers the
selected pulses to the multi-pass amplifier. The multi-pass
amplifier returns amplified seed-pulses to the E-O shutter. The
shutter rejects or transmits the amplified pulses depending on
whether the HV-pulse duration is respectively short or long.
Transmitted amplified pulses are delivered to a transient amplifier
configured for separately suppressing first-pulse
over-amplification and residual pulse leakage.
Inventors: |
KNAPPE; Ralf; (Trippstadt,
DE) ; SEIFERT; Albert; (Kaiserslautern, DE) ;
Weis; Alexander; (Kaiserslautern, DE) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
COHERENT KAISERSLAUTERN GMBH |
Kaiserslautern |
|
DE |
|
|
Assignee: |
COHERENT KAISERSLAUTERN
GMBH
Kaiserslautern
DE
|
Family ID: |
52625346 |
Appl. No.: |
14/022129 |
Filed: |
September 9, 2013 |
Current U.S.
Class: |
359/340 |
Current CPC
Class: |
H01S 3/2308 20130101;
H01S 5/041 20130101; H01S 3/10046 20130101; H01S 3/1106 20130101;
H01S 3/2316 20130101; H01S 3/11 20130101; H01S 3/0813 20130101;
H01S 3/09415 20130101; H01S 3/10015 20130101; H01S 3/2341 20130101;
H01S 3/08072 20130101; H01S 3/091 20130101 |
Class at
Publication: |
359/340 |
International
Class: |
H01S 5/04 20060101
H01S005/04 |
Claims
1. Optical apparatus comprising: a mode-locked laser delivering a
first train of pulses at a first pulse-repetition frequency (PRF);
at least one transient optical amplifier having a solid-state
gain-element optically pumped by radiation output from a
diode-laser array for energizing the gain-element, the diode laser
array having selectively variable output power; a multi-pass
optical amplifier; an optical shutter arranged to select pulses
from the first train thereof to provide a second train of pulses at
a second PRF less than the first PRF, provide the selected pulses
to the multi-pass amplifier to be amplified, receive a
corresponding train of amplified pulses from the multi-pass
amplifier and selectively transmit a plurality of pulses from the
train of amplified pulses to the transient optical amplifier for
further amplification, with pulses in the plurality thereof having
about equal amplitude; wherein the diode-laser array power is set
at a first level when amplified pulses are not being received to
maintain about constant thermal lensing in the gain-element, set at
a second level lower than the first level for a predetermined first
time period in response to the plurality of pulses being selected
for depleting stored energy in the gain-element, and set to a third
level higher than the first level for a second time period prior to
the arrival of the plurality of amplified pulses from the optical
shutter to restore stored energy in the gain-element, with the
first and second time periods being selected such that, when
further amplified, all further-amplified pulses in the plurality
thereof have about equal amplitude; and wherein the transient
amplifier has a laser resonator including the gain-element, the
laser-resonator generating CW radiation in response to the
first-level pumping when amplified pulses are not being further
amplified.
2. The apparatus of claim 1, wherein the optical shutter includes a
Pockels cell operable alternatively by a first high-voltage signal
of a first duration or a second high-voltage signal of a second
duration longer than the first duration, and wherein the Pockels
cell is operated by either the first or second high-voltage signal
to select pulses from the first train thereof to provide the second
train of pulses at the second PRF to the multi-pass amplifier, and
operated by the second high voltage signal to transmit the
plurality of pulses from the train of amplified pulses to the
transient optical amplifier for further amplification.
3. The apparatus of claim 2, wherein the optical shutter includes a
first polarizing beam-splitter in the path of the first train of
pulses to the Pockels cell and a second polarizing beam-splitter in
the path of the first train of pulses from the Pockels cell to the
multi-pass amplifier.
4. The apparatus of claim 3, wherein if when the Pockels cell is
not operated by any of the first and second high-voltage signals
pulses from the first train thereof are transmitted by the second
polarizing beam-splitter and not provided to the multi-pass
amplifier.
5. The apparatus of claim 3, wherein when the Pockels cell is
operated by any one of the first and second high-voltage signals,
pulses from the first train thereof are reflected by the second
polarizing beam-splitter and provided to the multi-pass
amplifier.
6. The apparatus of claim 5, wherein when the Pockels cell is
operated by the first high-voltage signal amplified pulses are
reflected by the first polarizing beam splitter and not transmitted
for the further amplification, and when the Pockels cell is
operated by the second high-voltage signal amplified pulses are
transmitted by the first polarizing beam-splitter to the transient
amplifier for the further amplification.
7. The apparatus of claim 1, wherein the optical shutter includes a
Pockels cell operable alternatively by a first high-voltage or a
second high-voltage signal, with each signal having the same
duration, but with second high voltage signal initiated later than
the first signal by an amount less than the signal duration, and
wherein the Pockels cell is operated by either the first or second
high-voltage signal to select pulses from the first train thereof
to provide the second train of pulses at the second PRF to the
multi-pass amplifier, and operated by the second high voltage
signal to transmit the plurality of pulses from the train of
amplified pulses to the transient optical amplifier for further
amplification.
8. The apparatus of claim 7, wherein the optical shutter includes a
first polarizing beam-splitter in the path of the first train of
pulses to the Pockels cell and a second polarizing beam-splitter in
the path of the first train of pulses from the Pockels cell to the
multi-pass amplifier.
9. The apparatus of claim 8, wherein if when the Pockels cell is
not operated by any of the first and second high-voltage signals,
pulses from the first train thereof are transmitted by the second
polarizing beam-splitter and not provided to the multi-pass
amplifier.
10. The apparatus of claim 8, wherein when the Pockels cell is
operated by any one of the first and second high-voltage signals,
pulses from the first train thereof are reflected by the second
polarizing beam-splitter and provided to the multi-pass
amplifier.
11. The apparatus of claim 10, wherein when the Pockels cell is
operated by the first high-voltage signal amplified pulses are
reflected by the first polarizing beam splitter and not transmitted
for the further amplification, and when the Pockels cell is
operated by the second high-voltage signal amplified pulses are
transmitted by the first polarizing beam-splitter to the transient
amplifier for the further amplification.
12. The apparatus of claim 1, wherein the optical shutter includes
a Pockels cell operable alternatively by a first high-voltage
signal of a first duration or a second high-voltage signal of a
second duration longer than the first duration, and wherein the
Pockels cell is operated by either the first or second high-voltage
signal to select pulses from the first train thereof to provide the
second train of pulses at the second PRF to the multi-pass
amplifier, and operated by the first high voltage signal to
transmit the plurality of pulses from the train of amplified pulses
to the transient optical amplifier for further amplification.
13. The apparatus of claim 12, wherein the optical shutter includes
a Faraday isolator, a half-wave plate, and first polarizing
beam-splitter in the path of the first train of pulses to the
Pockels cell, and a second polarizing beam-splitter in the path of
the first train of pulses from the Pockels cell to the multi-pass
amplifier.
14. The apparatus of claim 13, wherein if when the Pockels cell is
not operated by any of the first and second high-voltage signals,
pulses from the first train thereof are reflected by the second
polarizing beam-splitter and not provided to the multi-pass
amplifier.
15. The apparatus of claim 13, wherein when the Pockels cell is
operated by any one of the first and second high-voltage signals,
pulses from the first train thereof are transmitted by the second
polarizing beam-splitter and provided to the multi-pass
amplifier.
16. The apparatus of claim 15, wherein when the Pockels cell is
operated by the second high-voltage signal amplified pulses are
transmitted by the first polarizing beam-splitter through the
half-wave plate to the Faraday isolator and directed by the Faraday
isolator out of the optical shutter, and when the Pockels cell is
operated by the first high-voltage signal amplified pulses are
reflected by the first polarizing beam-splitter to the transient
amplifier for the further amplification.
Description
TECHNICAL FIELD OF THE INVENTION
[0001] The present invention relates in general to first pulse
suppression in solid-state laser systems. The invention relates in
particular to first-pulse suppression and pulse-selection in
solid-state, pulsed, master oscillator power amplifier (MOPA
systems) using a mode-locked master oscillator.
DISCUSSION OF BACKGROUND ART
[0002] A high-power short pulse (a few picoseconds or less)
solid-state MOPA system for material processing applications
typically includes a mode-locked master oscillator which provides
seed-pulses in a train at a pulse repetition rate (PRF) of several
megahertz (MHz). A pulse-picker is provided for selecting single
pulses or bursts of pulses from the seed-pulse train for further
amplification at a lower PRF, for example, hundreds of kilohertz
(kHz). The selected pulses are amplified by one or more solid-state
amplifier stages. A fast process shutter, usually an electro-optic
(EO) modulator is used to select from the amplified pulses, those
that are delivered to material being processed.
[0003] The fast process shutter adds significant cost and
complexity to such a MOPA system. There is a need for a method and
apparatus for operating such a MOPA system without a fast process
shutter. This method and apparatus must avoid over-amplification of
the first pulse in a train to be delivered to the material being
processed.
SUMMARY OF THE INVENTION
[0004] In one aspect, optical apparatus in accordance with the
present invention includes a mode-locked laser delivering a first
train of pulses at a first pulse-repetition frequency (PRF). The
apparatus includes at least one transient optical amplifier having
a solid-state gain-element optically pumped by radiation output
from a diode-laser array for energizing the gain-element. The diode
laser has selectively variable output power. The apparatus further
includes a multi-pass optical amplifier cooperative with an optical
shutter. The optical shutter is arranged to select pulses from the
first train thereof to provide a second train of pulses at a second
PRF less than the first PRF, provide the selected pulses to the
multi-pass amplifier to be amplified, receive a corresponding train
of amplified pulses from the multi-pass amplifier and selectively
transmit a plurality of pulses from the train of amplified pulses
to the transient optical amplifier for further amplification. The
amplified pulses in the plurality thereof have about equal
amplitude. The diode-laser array power is set at a first level when
amplified pulses are not being received to maintain about constant
thermal lensing in the gain-element; set at a second level lower
than the first level for a predetermined first time period in
response to the plurality of pulses being selected for depleting
stored energy in the gain-element; and set to a third level higher
than the first level for a second time period prior to the arrival
of the plurality of amplified pulses from the optical shutter to
restore stored energy in the gain-element. The first and second
time periods are selected such that, when further amplified, all
further-amplified pulses in the plurality thereof have about equal
amplitude. The transient amplifier has a laser resonator including
the gain-element. The laser resonator generates CW radiation in
response to the first-level pumping when amplified pulses are not
being further amplified.
BRIEF DESCRIPTION OF THE DRAWINGS
[0005] The accompanying drawings, which are incorporated in and
constitute a part of the specification, schematically illustrate a
preferred embodiment of the present invention, and together with
the general description given above and the detailed description of
the preferred embodiment given below, serve to explain principles
of the present invention.
[0006] FIG. 1 schematically illustrates a MOPA in accordance with
the present invention including a mode-locked master oscillator,
followed by a Faraday Isolator, and delivering pulses at a first
pulse-repetition frequency, a multi-pass amplifier, and a fast
double-pass electro-optical (E-O) shutter between the master
oscillator and first and second transient amplifier stages.
[0007] FIG. 2 schematically illustrates details of one preferred
arrangement of the fast double-pass E-O shutter and multi-pass
amplifier of FIG. 1, with the E-O shutter including a Faraday
rotator, a half-wave plate, and a Pockels cell activated and
deactivated by a switched high voltage power supply, and a
functioning as a pulse-picker for selecting seed-pulses for
amplification in the multi-pass amplifier and selecting amplified
pulses for delivery to the first and second amplifier stages.
[0008] FIG. 2A is a graph of Pockels cell voltage as a function of
time in the double-pass E-O shutter of FIG. 2 schematically
illustrating selection of a seed-pulse for amplification, rejection
of the amplified seed-pulse, and disposal of a subsequent
seed-pulse.
[0009] FIG. 2B is a graph of Pockels cell voltage as a function of
time in the double-pass E-O shutter of FIG. 2 schematically
illustrating selection of a seed-pulse for amplification,
acceptance of the amplified seed-pulse for delivery to the
first-amplifier stage of FIG. 1, and disposal of a subsequent
seed-pulse.
[0010] FIG. 3A and FIG. 3B schematically illustrate, in timing
diagram form, a pump modulation scheme in accordance with the
present invention for preventing first pulse over-amplification in
the transient amplifier stages of FIG. 1.
[0011] FIG. 4 schematically illustrates one example in accordance
with the present invention of a transient amplifier stage of FIG. 1
configured for reducing residual pulse leakage from the amplifier
stage.
[0012] FIG. 5 schematically illustrates another example in
accordance with the present invention of a transient amplifier
stage of FIG. 1 configured for reducing residual pulse leakage from
the amplifier stage.
[0013] FIG. 6 schematically illustrates details of another
preferred arrangement of the fast double-pass E-O shutter and
multi-pass amplifier of FIG. 1, similar to the arrangement of FIG.
2, but wherein the Faraday rotator is replaced by a Faraday
isolator.
[0014] FIG. 7A and FIG. 7B are graphs of voltage as a function of
time, schematically illustrate an alternate mode of switching the
Pockels cell or the A-O modulator in the arrangements of FIG. 2,
and FIG. 6
DETAILED DESCRIPTION OF THE INVENTION
[0015] Referring now to the drawings, wherein like components are
designated by like reference numerals, FIG. 1 schematically
illustrates a master oscillator and power amplifier (MOPA) 10 in
accordance with the present invention. MOPA 10 includes a
mode-locked master oscillator (seed-pulse laser) delivering a train
of pulses at a first pulse-repetition frequency (PRF). The first
PRF is determined by the resonator length of the seed-pulse laser
and may be between about 10 and 200 MHz. A preferred seed-pulse
laser is a mode-locked neodymium-doped yttrium vanadate
(NdYVO.sub.4) laser providing seed-pulses of 10 picoseconds
duration and pulse-energy of about 10 nanojoules (nj) at a PRF of
50 MHz. The seed-pulses are designated in FIG. 1 and other drawings
by small non-barbed arrowheads.
[0016] The train of pulses from seed-laser 12 is directed by a
front-surface polarizer (polarizing beam-splitter) 14 into a fast
double-pass electro-optical (E-O) shutter 16. Shutter 16 is
activated and deactivated by a DC high-voltage (HV) power supply
17, which is switched between on and off states in response to a
binary gate-signal. One suitable such power supply is available
from Bergmann Messgeraete Entwicklung (BME) of Murnau, Germany as
Model dpp2b3. Here, it is assumed that the seed-pulses are
plane-polarized with the polarization-plane perpendicular to the
plane of the drawing, i.e., S-polarized with respect to front
surface polarizer 14. E-O shutter 16 selects seed-pulses from the
input train at a second PRF which is a sub-multiple of the first
PRF. In this regard, the E-O shutter functions as the pulse-picker
of the above-described prior-art MOPA.
[0017] The selected pulses are directed by a turning mirror 18 into
a multi-pass solid-state amplifier 20. Amplifier 20 amplifies the
selected seed-pulses and returns amplified seed-pulses via
turning-mirror 18 to the fast E-O shutter. Amplified seed-pulses
are designated by large, barbed arrowheads. Shutter 16 either
rejects the amplified seed-pulses or transmits the amplified
seed-pulses for further amplification according to the duration of
the "on" state of the shutter. The selected amplified seed-pulses
are returned to polarizer 14 with the polarization-plane of the
amplified seed-pulses rotated by 90.degree.. The selected amplified
seed-pulses, accordingly, are transmitted by polarizer 14 to be
further amplified, first by a transient solid-state amplifier 24,
then by a transient solid-state amplifier 26. Each transient
amplifier is supplied with a pump-modulation signal, the purpose of
which is explained further hereinbelow.
[0018] It should be noted here that two transient amplifiers are
depicted in MOPA 10, by way of example. Depending on pulse power
required, and the configuration of the transient amplifiers, there
may be only one transient amplifier, or more than two transient
amplifiers without departing from the spirit and scope of the
present invention.
[0019] FIG. 2 schematically illustrates details of the fast
double-pass E-O shutter and multi-pass amplifier of FIG. 1. In the
drawing, the polarization-orientation of seed-pulses and amplified
seed-pulses at various stages of progress is indicated by
designating the representative arrowheads with the letters P for
P-polarization, S for S-polarization or both, where one or the
other orientation is determined by the binary switching state of
the shutter.
[0020] Shutter 16 includes, listed in order of forward propagation
of a seed-pulse, a Faraday rotator 30; a half-wave plate 32; a
polarizing beam-splitter 34, here in a McNeille bi-prism (cube)
form; a Pockels cell 36, which is switched by the HV-supply of FIG.
1; and a polarizing beam-splitter 33. Multi-pass amplifier 20
includes a focusing lens 48; a solid state gain-element 40, for
example a Nd:YVO.sub.4 gain-element; a pump-through mirror 44; and
an end-mirror 46. In this configuration, a seed-pulse to be
amplified, directed into the amplifier by beam-splitter 33 and
turning mirror 18, makes four passes through the gain-element and
is returned along the original incidence path to mirror 18 and back
into shutter 16. The polarization-orientation of the pulse stays
the same during the amplification and return thereof. The amplifier
gain-element is energized by radiation E from pump-diode-lasers 42.
Pump through mirror 44 is highly reflective for the wavelength of
the seed-pulses (and the amplifier gain wavelength) and highly
transmissive for the diode-laser wavelength.
[0021] The combination of Faraday rotator 30 and half-wave plate 32
imparts a net, effective 90.degree. rotation of the
polarization-orientation of a seed-pulse, here from S-polarized to
P-polarized in the forward (into the shutter) direction. The
combination of Faraday rotator 30 and half-wave plate 32 imparts a
net effective zero rotation of the polarization-orientation in the
reverse (out of the shutter) direction. Pockels cell 36 provides
net effective 90.degree. rotation of the polarization-orientation
of a pulse in the forward direction or net effective zero or
90.degree. rotation of the polarization-orientation in the reverse
direction dependent on the switching state of the high-voltage
supply.
[0022] If during forward passage of a seed-pulse the Pockels cell
is switched to provide zero polarization rotation, the seed-pulse
will be transmitted by polarizing beam-splitter 33 to be caught by
a beam-dump 38. If during forward passage of a seed-pulse, the
Pockels cell is switched to provide effective 90.degree.
polarization rotation, the seed-pulse (s-polarized) will be
reflected out of the shutter by polarizing beam-splitter 33 to be
directed by mirror 18 into the multi-pass amplifier.
[0023] An amplified seed-pulse returned to shutter 16 by multi-pass
amplifier 20 has the same polarization-orientation (S-polarization)
as the original seed-pulse and is reflected by polarizing
beam-splitter 33 back to Pockels cell 36. The amplified pulse, on
leaving the Pockels cell, will be either S-polarized or
P-polarized, depending on whether the Pockels cell is switched to
prove respectively net 90.degree. or net zero polarization
rotation. If there is net zero rotation, the amplified seed-pulse
will remain S-polarized and will be reflected by polarizing
beam-splitter 34 into beam-dump 39.
[0024] If the Pockels cell is switched to provide net 90.degree.
rotation, the polarization-orientation of the amplified seed-pulse
will be switched from S-polarized to P-polarized and will be
transmitted by polarizing beam-splitter 34. As the combination of
Faraday rotator 30 and half-wave plate 32 provides net zero
polarization rotation in the reverse direction, after passage
through the half-wave plate and the Faraday rotator, the amplified
seed-pulse is transmitted by polarizing beam-splitter 14 to the
transient amplifier stages of FIG. 1. A description of the actual
operation of shutter 16 is set forth below with reference to FIG.
2A and FIG. 2B.
[0025] FIG. 2A schematically depicts first and second durations
D.sub.S (short) and D.sub.L (long) for HV (voltage-pulse)
application to the Pockels cell of FIG. 2. These durations are
measured from the instant of turning the HV on to the instant of
turning the HV off. The actual (steady-state) duration of the HV
application is DS or DL minus the rise-time of the voltage pulse.
Here, it is assumed that the HV application causes net 90.degree.
polarization rotation, which, of course, is independent of
propagation-direction. In FIG. 2A the HV is applied to the Pockels
cell only for the short duration D.sub.SS such that the
polarization-orientation of a seed-pulse SP.sub.N in a train
thereof from the seed-laser is rotated net 90.degree.. Rotating the
polarization-plane of the seed-pulse causes the seed-pulse to be
sent to the multi-pass amplifier for amplification. HV is switched
off, and falls to zero (or some low state) before the amplified
pulse returns to the Pockels cell. As such, the
polarization-orientation of the amplified seed-pulse AP.sub.N stays
S-polarized after a return path through the Pockels cell, and is
rejected (reflected) out of switch 16 by polarizing-beam-splitter
34 (see FIG. 2). Gain in the amplifier gain-element will, however,
have been depleted by the amplification of the seed-pulse. The
amplified seed-pulse traverses the Pockels cell at a time D.sub.R
after the corresponding seed-pulse has traversed the Pockels cell.
D.sub.R, of course depends on the optical path length of the
seed-pulse from the Pockels cell through the amplifier and back to
the Pockels cell
[0026] It can also be seen in FIG. 2A that HV is not turned back on
until at least the next seed-pulse (SP.sub.N+1) in the train
thereof from the seed-pulse laser has traversed the Pockels cell,
at least pulse-SP.sub.N+1 is not polarization-rotated by the
Pockels cell and is transmitted by polarizing beam-splitter 33 as
discussed above with reference to FIG. 2 Accordingly, by
synchronizing the HV switching with the seed-pulsed laser PRF every
M.sup.th seed-pulse can be transmitted to the amplifier in a train
thereof having a PRF one M.sup.th that of the seed-pulse laser PRF.
This provides a pulse-picker function for the inventive MOPA. In
steady state operation, the pump-power supplied to the multi-pass
amplifier gain-element can be balanced with the PRF of the "picked"
(delivered to the multi-pass amplifier) seed-pulses such that all
amplified seed-pulses have the same amplitude, whether or not the
amplified seed-pulses are selected for delivery to the transient
amplifier stages of FIG. 1. This eliminates the giant-pulse effect
of a first-delivered amplified pulse in a train, regular or
irregular.
[0027] FIG. 2B schematically illustrates the manner in which an
amplified seed-pulse is selected for delivery from the fast E-O
shutter. Here it is assumed that every 25.sup.th one of the
seed-pulse lasers is picked from the train thereof from the seed
laser and delivered to the multi-pass amplifier, and seed-pulse
SP.sub.N+25 is delivered to provide a corresponding amplified pulse
AP.sub.N+25 for delivery to the transient amplifiers. In order to
realize this, HV is applied to the Pockels cell for the long
duration D.sub.L such that the polarization-orientation of AP is
rotated by the Pockels cell from S-polarized, to P-polarized. This
provides that amplified pulse is transmitted by polarizing
beam-splitter 34 and by polarizing beam-splitter 14 to the
transient amplifier stages. This provides the above described fast
process shutter function of the above described prior-art MOPA and
eliminates the need for a separate such shutter. The delivery form
of the amplified seed-pulses can be regular or irregular, and need
not correspond to the delivery rate of picked seed-pulses to the
multi-pass amplifier, while still providing that each seed-pulse
delivered for further amplification has the same amplitude.
[0028] In general terms, duration D.sub.L is preferably equal to
about the reciprocal of the seed-pulse laser PRF and the rise-time,
and in particular the fall time, of the HV pulses, long or short,
should be less than the delay time D.sub.R between a delivered
seed-pulse and a corresponding returned amplified seed-pulse. This
will provide, with proper synchronization of the Pockels cell
switching, that the operation of FIG. 2A can be accomplished
without pulse AP.sub.N being "intercepted" by the falling edge of
the HV pulse; and that the operation of FIG. 2B can be accomplished
without pulse AP.sub.N+25 and seed-pulse SP.sub.N+26 being
intercepted by the falling edge of the longer HV pulse.
[0029] In specific terms, if the seed-pulse PRF from the seed-pulse
laser is the above-exemplified 50 MHz, then D.sub.L should be about
20 nanoseconds (ns). Picking every 25.sup.th seed-pulse for
amplification will correspondingly require that the Pockels cell
can be switched at a rate of 2 MHz which is possible with currently
available HV power supplies and switches. Switching rise and fall
times of less than 6 ns are possible with such switches.
[0030] Given above discussed exemplary seed-pulses of between about
60 nanojoules (nj) and about 90 nj pulse-energy and about 10 ps
pulse-duration, and with multi-pass amplifier 20 having a
NdYVO.sub.4 gain-element between about 12 millimeters (mm) and
about 30 mm long and pumped with between about 25 Watts (W) and
about 80 W of pump radiation, amplified seed-pulses having a
pulse-energy of between about 10 microjoules (mj) and 200 mj, and
equal amplitude of up to 20 W, will be delivered from fast E-O
shutter 16 for further amplification in transient amplifiers 24 and
26 as depicted in FIG. 1. Each transient amplifier must be
configured to at least avoid over-amplification of a first pulse in
a train in order to retain the benefit of equal-amplitude amplified
seed-pulses provided by fast E-O shutter 16 in combination with
multi-pass amplifier 20. A method in accordance with the present
invention for first-pulse suppression for the transient amplifiers
is pump-modulation. In this method an amplifier gain-element is
pumped at a lower-than-consistent level for some time interval
prior to the arrival of a first pulse, then restored to the
consistent level, beginning at some interval immediately before the
arrival of the first pulse in the train. The pump-power is then
retained at the consistent level for amplification of the first and
all other pulses in the train. This is illustrated in
timing-diagram form in FIG. 3A and FIG. 3B
[0031] FIG. 3A schematically illustrates a binary gate-signal used
to request delivery of amplified seed pulses, as discussed above
with reference to the inventive combination of fast E-O shutter 16
and multi-pass amplifier 20. The gate-signal is at digital low when
pulses are not being requested and digital high when pulses are
being requested. With the gate-signal at low, the gain element of a
transient amplifier is pumped at a level (Level-1 in FIG. 3B)
sufficient to maintain the gain element at a temperature which is
the same as the temperature during pulses delivery. This is to keep
thermal lensing by the gain-element constant. Note that 3B depicts
pump-diode current as a function of time. Further, it is noted that
the spikes shown in FIG. 3B under pulse train are intended to show
the pulse train being generated during the period when the current
supplied to the pump diodes is at Level-3.
[0032] Continuing with reference to FIG. 3A and with reference in
addition to FIG. 3B, when the gate-signal goes high to request
pulse-delivery, the pump-power (diode-current) is switched to a
lower level (Level 2) for a time period T.sub.X. This power level
is sufficient to keep the pump-diodes lasing but at a level low
enough that stored energy in the gain-element is significantly
depleted. It is also possible to lower the power below lasing
threshold for the diodes. Time T.sub.X is short enough that no
significant temperature change in the gain-element occurs, but long
enough to provide the required depletion of stored energy in the
gain-element. In terms of the above example of pulse power and
repetition rate, T.sub.X is about 100 microseconds (.mu.s).
[0033] At a time T.sub.Y before the arrival at the amplifier of the
first pulse in a train to be amplified, the pump-power is switched
to a level which provides for constant amplitude of amplified
pulses. T.sub.Y is selected such that the stored energy in the
gain-element will be at a level at which the stored energy will be
on arrival of all subsequent pulses. Time T.sub.Y can be
calculated, or simply determined by experiment, for any particular
level-3 pump-power and PRF of pulses in the pulse train.
[0034] While the above-described pump-modulation method is highly
effective for avoiding over amplification of the first pulse in a
train thereof, the method has a disadvantage in that residual pulse
leakage from the amplifier is increased, absent any measures to
reduce such leakage. Residual pulse leakage is primarily amplifier
output resulting from amplification of uncontrolled small
picosecond pulses from the multi-pass amplifier. These pulses can
occur, for example as a result of incomplete blockage of seed
pulses or amplified seed-pulses by polarizing beam-splitters fast
optical shutter 16. This leakage is not depicted in FIG. 3B for
simplicity of illustration. A transient amplifier in accordance
with the present invention configured for reducing such residual
pulse leakage is schematically illustrated in FIG. 4.
[0035] Here, a transient amplifier is depicted, which can be either
transient amplifier 24 or transient amplifier 26 of FIG. 1. This
amplifier includes a gain-element which is continuously pumped by
pump-radiation from array 70 of diode-lasers. These diode-lasers
are operable responsive to a pump-current modulation signal, as
depicted in 3B, for preventing over-amplification of a first pulse
in a train thereof to be amplified. The pump-radiation is delivered
through a dichroic mirror 56 which is highly reflective at the
pulse-wavelength, i.e., the emission wavelength of the gain
element, and highly transmissive for the wavelength of the
pump-radiation.
[0036] Input pulses to be amplified are S-polarized with respect to
a polarizing beam-splitter 52, and accordingly, are reflected by
that beam-splitter. The pulses are then reflected by a turning
mirror 54 through gain-element 50 for amplification. Amplified
pulses exit gain-element 50 and are reflected by dichroic mirror 56
and another polarizing beam-splitter 58 out of the amplifier,
either as output pulses of MOPA 10, or to a further transient
amplifier stage.
[0037] A laser resonator 60 is formed between end mirrors 62 and
64. When pulses are not being amplified, this causes lasing in the
laser resonator. Laser radiation in the resonator is caused to be
P-polarized with respect to the beam-splitter surfaces due to the
presence of the beam-splitters. Both mirrors 62 and 64 are
partially transparent, allowing CW laser output from each end of
resonator 60. The output radiation is caught by beam dumps 66 and
68. Output at both ends of resonator 60 is advantageous in that
radiation is dumped at two different locations, thereby
distributing heat load in the amplifier. Dumping at only one end of
resonator 60 is possible with good thermal management. When CW
laser radiation is being generated, thereby extracting gain from
the gain-element, residual pulse leakage along the pulse output
path is eliminated (or greatly reduced). When pulses are being
amplified, gain in element 50 is depleted below threshold for the
CW lasing, and the CW lasing stops. This arrangement is
particularly suited for a gain-element of YVO.sub.4 which has a
much higher gain in one crystal plane than in a crystal plane at
90.degree. to that plane. In this case, the strong-gain plane of
the gain-element (crystal) is aligned with the polarization-plane
of the pulses being amplified.
[0038] FIG. 5 schematically illustrates an alternate arrangement of
either amplifier 22 or amplifier 24. This arrangement is similar to
the arrangement of FIG. 4 with an exception that, when pulses are
not being amplified CW lasing is established at a gain-wavelength
(.lamda..sub.2) of element 50 different from the wavelength
(.lamda..sub.1) of the pulses to be amplified. By way of example,
Nd:YVO.sub.4 has a gain-line at a wavelength of 1342 nm. This line
has a lower emission cross-section (weaker gain) than at the
primary line of 1064 nm. In the transient amplifier arrangement
FIG. 5, dichroic mirrors 72 and 74 replace the polarizing
beam-splitters of the amplifier arrangement of FIG. 4. These
dichroic mirrors are reflective at the pulse (strong-gain)
wavelength and highly transmissive at the weak-gain wavelength. End
mirrors 62A and 64A, which are partially reflective and partially
transmissive, at the weak-gain wavelength, replace end mirrors 62
and 64 of the amplifier arrangement of FIG. 4. When pulses are not
being amplified, CW lasing occurs in resonator 60 at the weak-gain
wavelength, thereby extracting gain for element 50 and suppressing
residual pulse leakage along the pulse-output path. It is also
possible to create a laser-resonator including gain-element 50 by
coating minors directly on the ends of the gain-element.
[0039] The amplifier arrangements of FIG. 4 and FIG. 5 are two
preferred pulse-amplifier arrangements in accordance with the
present invention configured for separately suppressing residual
pulse leakage, and prevent first-pulse over-amplification. Other
possible arrangements include arranging the resonator axis path at
an angle to the amplified pulse path for separating the two paths,
and using a dumped CW beam from one amplifier stage to extract gain
from the gain-element in a subsequent amplifier stage. Dumped
amplified seed-pulses from the E-O shutter may also be used for
gain-extraction. From the description presented herein, those
skilled in the art may devise other configurations for separately
suppressing residual pulse leakage and preventing first-pulse
over-amplification without departing from the spirit and scope of
the present invention.
[0040] Continuing now with a description of other embodiments of
the inventive MOPA, in particular another arrangement of the fast
EO-shutter, FIG. 6 schematically illustrates details of another
preferred arrangement of the fast double-pass E-O shutter and
multi-pass amplifier of FIG. 1, similar to the arrangement of FIG.
2, but wherein Faraday rotator 30 is omitted and replaced by a
Faraday isolator. The combination of Faraday isolator 15 and
half-wave plate 32 is arranged to provide net zero
polarization-rotation for forward propagating seed-pulses. The
Pockels cell is configured to provide net zero
polarization-rotation in the no (or low) HV applied state. In this
state, the polarization-plane of seed-pulses is not rotated and the
seed-pulses (P-polarized) are reflected out of the shutter by
polarizing beam-splitter 33.
[0041] When operated by the long or short HV pulse duration
switching method of FIGS. 2A and 2B, the long duration (D.sub.L)
pulse is used for admitting a seed-pulse to amplifier 20 and
discarding the corresponding amplified seed-pulse. With this HV
pulse applied, the Pockels cell provides net 90.degree.
polarization rotation; the seed-pulse is transmitted through
beam-splitter 33 to the amplifier. The corresponding, S-polarized
amplified seed-pulse returns through beam-splitter 33 and becomes
P-polarized on passing through the Pockels cell. The pulse passes
through beam-splitter 34, to be rejected by Faraday isolator
15.
[0042] The short duration (D.sub.S) HV pulse is applied to the
Pockels cell for admitting a seed-pulse to amplifier 20 and
delivering the corresponding amplified seed-pulse to the transient
amplifiers. With this short-duration HV pulse applied to the
Pockels cell, the seed-pulse is 90.degree. polarization-rotated and
transmitted through beam-splitter 33 to the amplifier. The
corresponding, S-polarized amplified seed-pulse returns through
beam-splitter 33 and passes the Pockels cell without polarization
rotation. The S-polarized amplified seed-pulse is reflected out of
shutter 16B to the transient amplifiers by beam-splitter 34.
[0043] From the description present above, those skilled in the art
may devise other arrangements of the optical shutter and amplifier
combination. Such arrangements may include using an acousto-optic
switch (driven by high RF-voltage) in place of the Pockels cell,
but probably with inferior performance. These and any other
arrangements may be adopted without departing from the spirit and
scope of the present invention. A description of alternate binary
switching scheme for fast optical shutter 16 and above-described
embodiments thereof is set forth below with reference to FIG. 7A
and FIG. 7B.
[0044] The alternative binary switching scheme carries out the
operations of FIGS. 2A and 2B, but with the alternative
short-duration and long-duration HV pulses replaced by a pulse of a
long fixed duration (D.sub.F) switched at one of two time periods
(T.sub.1 and T.sub.2) following receipt of a seed-pulse from laser
12 of FIG. 1. FIG. 7A schematically illustrates the fixed-duration
(D.sub.F) pulse applied (switched-on) with time T.sub.1 immediately
following seed-pulse SP.sub.N-1. Seed-pulse SP.sub.N traverses the
Pockels cell while the HV pulse is applied and amplified seed-pulse
APN returns after the HV pulse has been switched off. In the
arrangement of FIG. 2, this would be used for picking every
M.sup.th pulse from the input train for transmission to amplifier
20, but preventing the corresponding amplified-seed-pulse from
being transmitted to the transient amplifiers. In the arrangement
of FIG. 6 this would be used for sending a seed-pulse to amplifier
20 and transmitting the corresponding amplified seed-pulse to the
transient amplifiers
[0045] FIG. 7B schematically illustrates the fixed-duration
(D.sub.F) pulse applied (switched-on) with time T.sub.2 following
seed-pulse SP.sub.N+24 by an arbitrarily-selected time D.sub.F/2.
This arbitrary switching time is long enough that seed-pulse
SP.sub.N+25 and corresponding amplified seed-pulse AP.sub.N+25
traverse the Pockels cell while the HV pulse is applied, but short
enough that the seed-pulse SP.sub.N+26 traverses the Pockels cell
after the HV pulse has been switched off. In the arrangement of
FIG. 2, this would be used for transmitting a seed-pulse to
amplifier 20 and providing the corresponding amplified-seed-pulse
is transmitted to the transient amplifiers. In the arrangement of
FIG. 6, this would be used for picking every M.sup.th pulse from
the input train for transmission to amplifier 20, but preventing
the corresponding amplified-seed-pulse from being transmitted to
the transient amplifiers.
[0046] In summary, the present invention is described above in
terms of a preferred and other embodiments. The invention is not
limited, however, to the embodiments described and depicted herein.
Rather, the invention is limited only to the claims appended
hereto.
* * * * *