Vladimir RUBTSOV -- Puke Ray / LED Incapacitator; article
& US Patent

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**Vladimir RUBTSOV**

**Puke Ray**



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**[http://Wired.com](http://wired.com/)
( 6 August 2007 )**

**Puke Ray**

**By Noah Shachtman**

Government-funded researchers are building a flashlight
that makes people puke on command.

The LED Incapacitator uses a range-finder to measure the
distance to a target's eyes, *Threat Level* notes. Then
it unleashes continually changing, multi-color light pulses that
make the target feel bad -- really bad. The "effects, whose
effectiveness depends on the person, range from disorientation
to vertigo to nausea," according to *Technology Review*.

The trick isn't trying to figure out which light-pulse sequence
will make people hurl. "Thereas one wavelength that gets
everybody,a says Robert Lieberman, who along with his partner
Vladimir Rubtsov, is developing the Incapicator for the
Department of Homeland Security. aVlad calls it the evil color.a

The tough part for Lieberman and Rubstov is getting the thing
down to a manageable size, a DHS newsletter notes.

*At 15 inches long by 4 inches wide, the current prototype is
more transportable than portable. The next-generation weapon
must be as short and svelte as a D-cell Maglite, designed to
fit on a duty belt. aPhase 3 will be our shrink phase,a
Lieberman says.*

There's also talk of making the weapon bigger, too.
"immobilizing a mob, for instance, might call for a wide-angle
'bazooka' version," the newsletter muses. But even king-sized
vomit-lights could have some pretty obvious countermeasures, *Technology
Review* notes. "The person being targeted could easily
look away, or he or she might be wearing heavily tinted
glasses."

Harder to beat would be a radio-frequency puke ray. Lucky for
us, the Navy is backing one of those, too.

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**US Patent # 7,180,426**

**Incapacitating Flashing Light Apparatus
and Method**

**February 20, 2007**

**Vladimir Rubtsov**

**Abstract**

Apparatus and method for using an light source to incapacitate
a subject in which the light source strobes by a spatial
scanning through a pattern and a temporal flashing at a rate
sufficient to cause incapacitation. The strobing (meaning both
spatial scanning and temporal flashing is in a pattern to
prevent the subject from escaping the strobing effect. The
flashing is timed so that each flash point in the pattern will
flash at a rate and sequence to cause incapacitation. In a
preferred embodiment, the light source is an array of LEDs or
laser diodes.

Inventors:  Rubtsov; Vladimir (Los Angeles, CA)   
Assignee:  Optech Ventures, LLC (Torrance, CA)

Current U.S. Class:  340/815.4 ; 340/321; 340/573.1;
340/574; 340/815.75; 361/232; 362/259; 42/1.08   
Current International Class:  G08B 5/00 (20060101)   
Field of Search: 
340/815.4,815.43,815.49,815.69,815.75,321,573.1,574,691.7,693.5
116/7,202 362/259 361/232 222/39 42/1.08   
References Cited:   
U.S. Patent Documents: 5556003 // 5644297 // 5949338 // 6144302
// 6791816 // 6898887

**Other References**

American National Standards Institute, American National
Standard for Safe Use of Lasers, ANSI 2136.1-2000, 1993, USA.
cited by other .   
Richard Dennis, James Harrison, Visual Effects of the Green
Laser-Baton Illuminator (GLBI), May 2001, U.S. Air Force
Research Laboratory, Texas, USA. cited by other .   
Leon N. McLin et al., The Laser Threat, U.S. Air Force (USAFSM),
Colorado, USA. cited by other .   
Visual Impairment Brain Waves Paper. cited by other .   
Sidney S. Charschan, Evolution of Laser Safety Standards ANSI
2136.1s, Journal of Laser Applications, Dec. 1998, vol. 10,
Issue 6, USA. cited by other .   
Vladimir Rubstov, High Intensity Laser with Fiber Optic
Multidirectional Strobe, Intelligent Optical Systems. cited by
other.

**Description**

**FIELD OF THE INVENTION**

The invention relates to devices for using flashing light to
incapacitate a person or other animal.

**BACKGROUND**

Security devices using light are known.

In U.S. Pat. No. 6,007,218 a laser based security device is
shown that uses visual laser light at predetermined wavelengths
and intensities to create temporary visual impairment to cause
hesitation, delay, distraction and reductions in combat and
functional effectiveness.

In U.S. Pat. No. 6,190,022 a visual security device is shown
that uses sequentially flashing multiple LEDs.

The references listed herein also provide background.

**SUMMARY**

In one aspect the invention is a device for incapacitating a
subject using a source of a beam of light by strobing (as
defined herein).

In one aspect the invention is a device for incapacitating a
subject using an array of light emitting elements by strobing
(as defined herein).

In another aspect the invention is such an incapacitating
device in which the light emitting elements are an array of
LEDs.

**BRIEF DESCRIPTION OF THE DRAWINGS**

**FIG. 1** is a schematic view of an exemplary embodiment of
the invention.

![](7180-1.jpg)

**FIG. 2** is a schematic view of an exemplary embodiment of
the invention.

![](7180-2.jpg)

**FIG. 3a** is a drawing of an exemplary flash pattern.

![](7180-3a.jpg)

**FIG. 3b** is a drawing of another exemplary flash pattern.

![](7180-3b.jpg)

**FIG. 4a** is a time graph for the sequencing of scanning
and flashing for the flash pattern of FIG. 3a.

![](7180-4a.jpg)

**FIG. 4b** is a time graph for the sequencing of scanning
and flashing for the flash pattern of FIG. 3b

![](7180-4b.jpg)

**FIG. 5** shows the different levels of physiological
effects that are produced from visual impairment induced by
varies levels of irradiance based on a single exposure of 0.25
seconds (aversion time) from which MPE is 2.6 miliwatt/square cm
as described in reference 2.

![](7180-5.jpg)

**DESCRIPTION**

Following is a description of the invention sufficient to
enable it to be practiced and extending to the best mode or
modes of the invention known to the inventor.

In one aspect the invention is a method and apparatus for
incapacitating a person or other animal (referred to as the
subject or target) by causing a light source to have a temporal
flash component and a spatial scan component. The spatial scan
component will create a pattern by means of positions in the
apparatus that result in flash points in space to define a
scanned area. In one aspect the invention is a method and
apparatus for incapacitating a person or other animal by use of
an array of light emitting elements having a temporal flash
component and a spatial scan component in a repeating pattern
such that at each repetition of a given position in the pattern
a flash rate occurs within the range of flash rates that will
cause some level of incapacitation. When a plurality if light
emitting elements is used each may be equipped with a
collimator, or a combined beam former may be used to transform
the wide angle of the LEDs to a narrow beam. The exposure of the
subject to the flashing light is not necessarily limited to
avoiding permanent injury or lethality. However, in one aspect
the invention is defined in relation to the MPE (maximum
permissible exposure) as defined in Laser Institute of America
ANSI Z136.1-2000, Safe Use Of Lasers (reference 1) so as to not
exceed the MPE.

In one aspect of the invention the spatial scan rate and the
temporal flash rate are selected such that in each cycle of the
pattern at least one flash occurs at each flash point.

In accordance with the invention, it is important that light
energy be delivered to a target area that includes an area
greater than the beam footprint. This prevents the subject from
escaping the effect of the flashing. This is done by setting the
device to a sequence of directions to visit a sequence of flash
points to result in a pattern that defines an area in space. In
such a case, it is necessary to spatially scan the beam through
a sequence of positions while flashing to ensure the delivery of
the energy to effect some level of incapacitation. The direction
of the beam and the number of flashes to occur in each position
may be achieved in a number of different ways. Two examples are
presented. The first involves a flash rate that is so much
faster than the spatial scan rate that the beam direction
revisits each position in the scan sequence and consequently
each flash point in space at a rate such that at least one flash
occurs at each flash point. The second is that the spatial scan
rate is so much greater than the flash rate that not every flash
point is flashed at each spatial scan cycle.

These conditions are controlled by three variables: A = scan
rate, the time for spatial scan of the entire pattern in
cycles/unit time; B = flash rate, the time in flashes/unit time;
and C = number of positions or flash points in the pattern;

whereby the relationship that defines the sequence of temporal
flashing and spatial scanning within the pattern is given by:

![](eq1.jpg)

wherein flashes may occur once or a multiple of times at each
flash point per spatial scan cycle, or may skip one or more
flash points per spatial scan cycle.

The term strobe or strobing is be used in this description and
in the claims as having a special definition, meaning a
combination of a spatial scan component being the movement of
the beam and of a temporal flash component representing the
flashing of the light emitting elements. Strobing is utilized to
create a flash pattern also called a target configuration. A
flash pattern is established by the spatial scan component to
provide a set of flash points in space each flash point
representing one direction of the beam footprint. Typically the
flash points are illuminated in a flash order which in one
embodiment is repeated to define the flash pattern. A flash is
defined as being repeated in an ordered sequence when there is
some geometric relationship to the sequence such as adjacent
flash points. One or both components of the strobe or strobing,
the spatial and the temporal, can be set fixedly or be
adjustable. When all the flash points of a flash pattern have
been visited, either with one or more flashes or not, a flash
pattern cycle is completed. Also, as will be explained in more
detail below, the flash order may be set to a regular geometric
relationship such as with the flash pattern spatially scanning
through adjacent flash points, or it may be set in a randomized
flash order that repeats itself in each cycle. Although it is
practical to cause the flash order to repeat by use of a CPU
controlled and programmed device the flash order can vary for
each cycle.

In one embodiment each flash point is flashed at least once in
each spatial scan cycle. Although this may be done in an ordered
sequence as described above, it may also be done in a randomized
sequence. In either case the sequence may be constantly repeated
or may be varied such as by different ordered sequences or by
different randomized sequences. For example, a set of X
different randomized flash patterns can be programmed, which
repeat.

In another aspect the target of exposure is exposed to an
amount of irradiance not exceeding the MPE (as designated in
ANSI Z136.1-2000) in order to cause less than permanent injury
to the eyes.

These and other aspects of the invention will be apparent from
the following description(s) of embodiments of the invention.

FIG. 1 shows in schematic form, an apparatus 10 constructed in
accordance with the invention. The apparatus 10 has a case 12 in
which are contained the operating components. These are a power
supply 14, an electrical control module 16, a scan module 18, a
light emitting module 20 and a lens or beam former 22.

The case 12 can be generally elongated to carry the components,
although any workable arrangement of the components and
configuration of the case 12 is within the scope of the broad
concept of the invention. It has a rear handle 24 and a lower
handle 26 adapted to enable it to be held and operated by hand.
Also it has a mounting receptacle 28 for attaching any kind of
stand for holding it in a steady and controllable position.
Although the flash pattern is designed to trap a subject in the
pattern, that is to be large enough that incapacitation will
occur before the subject can escape from the pattern; it is also
possible that the user can traverse the apparatus as the subject
moves in order to keep the subject closer to the middle of the
scan pattern and in any event to keep the subject in the pattern
as long as necessary.

The power supply 14 can be a rechargeable battery along with or
alternatively, a receptacle for an external power source. A
battery life indicator 30 is shown as well as contacts 32a and
32b.

The electrical control module 16 has an electrical input and
control element 34 connected to the power supply 14 by contacts
36a and 36b and a spatial scan control element 38 that has
circuitry and processing elements for allowing the spatial scan
and temporal flash to be set and controlled. An adjusting
mechanism 40 allows the spatial scan rate and temporal flash
rate to be changed.

In one embodiment the spatial scan module 18 has a vertical
scanner mechanism 42 and a horizontal scanner mechanism 44. In
one embodiment the vertical scanner 42 is a linear actuator or
incrementer that will operate in specific, and if desired,
adjustable vertical increments while the horizontal scanner 44
is a continuous reciprocating scan device operating over a
horizontal reciprocal range and if desired it can have an
adjustable (in either or both speed and range) mode. These could
be reversed. Where a continuous motion of scanning is used the
flash points are defined by the event of flashing; and where a
stepping device is used the flash points may be defined by a
mechanical position.

The light emitting module 20 has a control frame 46 extending
from the scan module 18 to an light element support frame 48 on
which are mounted a heat sink 50 and a light source 52.

FIG. 2 shows in schematic form, an alternative apparatus 100
constructed in accordance with the invention. The apparatus 100
has a case 102 in which are contained the operating components.
These are a power supply 104, an electrical control module 106,
a scan module 108, a light emitting module 110 and a lens or
beam former 112.

The case 102 can be generally elongated to carry the
components, although any workable arrangement of the components
and configuration of the case 102 is within the scope of the
broad concept of the invention. It has a rear handle 114 and a
lower handle 116 adapted to enable it to be held and operated by
hand. Also it has a mounting receptacle 118 for attaching any
kind of stand for holding it in a steady and controllable
position. Although the flash pattern is designed to trap a
subject in the pattern, that is to be large enough that
incapacitation will occur before the subject can escape from the
pattern; it is also possible that the user can traverse the
apparatus as the subject moves in order to keep the subject
closer to the middle of the scan pattern and in any event to
keep the subject in the pattern as long as necessary.

The power supply 104 can be a rechargeable battery along with
or alternatively, a receptacle for an external power source. A
battery life indicator 120 is shown as well as contacts 122a and
122b.

The electrical control module 106 has an electrical input and
control element 124 connected to the power supply 104 by
contacts 126a and 126b and a spatial scan control element 128
that has circuitry and processing elements for allowing the
spatial scan and temporal flash to be set and controlled. An
adjusting mechanism 130 allows the spatial scan rate and
temporal flash rate to be changed.

In one embodiment the spatial scan module 108 has a vertical
scanner mechanism 132 and a horizontal scanner mechanism 134. In
one embodiment the vertical scanner 132 is a linear actuator or
incrementer that will operate in specific, and if desired,
adjustable, vertical increments while the horizontal scanner 134
is a continuous reciprocating scan device operating over a
horizontal reciprocal range and if desired it can have an
adjustable (in either or both speed and range) mode. These could
be reversed. Where a continuous motion of scanning is used the
flash points are determined by the event of flashing; and where
a stepping device is used the flash points may be determined by
a mechanical position.

The light emitting module 110 has a control frame 136 extending
from the scan module 108 to an light element support frame 138
on which are mounted a heat sink 140 and an array of LEDs (light
emitting diodes) 142 on a mounting platen 144. The light
emitting module 110 is held in place by a flexible support ring
146 that allows the light emitting module 110 to pivot as it is
moved in the spatial scan component of the strobe function.

The LED array 142 can be an array of discrete LEDs or it can be
one or more LED clusters.

The beam former 112 is an optical element that functions to
form a desired beam 148 from the light emitted by the LED array
142. The beam angle X defines the size of the spot of a single
flash point on the target. The beam diameter at the exit of the
beam former defines the observed aperture x.sub.1--x.sub.1.
Other light emitting elements can be employed. For use of
coherent light sources, a laser source can be employed with
optical fibers carrying the laser light from a single laser at
an input end to an output end the output ends being arranged in
an array. Alternatively a plurality of lasers in an array could
be employed. By use of coherent light, with less divergence,
longer operating ranges are possible.

Other light emitting elements include laser diodes used in the
same manner as the LEDs, in which case a beam combiner or/and a
beam expender could be used.

The beam can be formed in other ways. In one aspect each light
emitting element can have its own beam former. In the case of
LEDs each one can have its own collimator.

Scanning can be accomplished by other than the mechanical means
shown above. An electro-optical scanning element such as an
electro-optical crystal lens such as a lithium niobate crystal
can be placed in front of the beam former or formers. An
opto-mechanical scanner such as cylindrical cartridge containing
a number of optical fibers equal to the number of flash points
could be employed. The fibers are organized at the output in
such a manner that light flashes from the end of the fibers
cover the predefined area during axial rotation of the
cartridge. Also liquid crystals can be used for scanning.

FIGS. 3a and 3b show an exemplary target configuration 170, in
this example made up of four rows r1, r2, r3, and r4 and four
columns c1, c2, c3, and c4 representing flash exposure points
for each flash of the LEDs as they are scanned and incremented.

In FIG. 3a the target configuration 170 is a flash pattern
having 16 flash points in a 4 by 4 matrix or pattern that
operates through a strobing sequence as illustrated in FIG. 2a
in which the spatial component starts at the flash point r1, c1
and moves horizontally to r1, c4 and then is both incremented
vertically down and reversed horizontally to r2, c1 and then
strobes through r2, c4 and so on. After the flash at r4, c4 the
scanner and incrementer return to flash at r1, c1 and the
sequence is repeated. The chart for that sequence is shown in
FIG. 4a.

In FIG. 3b there is shown the same 4 by 4 pattern with an
alternative strobe sequence in which the spatial component
differs starting at the flash point r1, c1 and scanning
horizontally to the right to r1, c4 and then incrementing
vertically to r2, c4 and then scanning horizontally to the left
to r2, c1 then incrementing vertically to r3, c1, then scanning
horizontally to the right to r3, c4, then incrementing
vertically to r4,c4 and then scanning horizontally to the left
to r4, c1 and then incrementing upward to r1, c1 to begin the
sequence again. The chart for that sequence is shown in FIG. 4b.

In each of the examples of FIGS. 3a and 3b, the sequence could
be rotated ninety degrees so that scanning occurs vertically and
incrementing occurs horizontally.

The foregoing described sequences through adjacent flash
points. But the sequence could be randomized to a selected
repeating order of flashes. The flash order should repeat after
each cycle. Moreover, through programming options, the user can
be enabled to select a pattern through adjacent flash points or
randomized repeating or even randomized varying (in which the
cycle is completed but differently each time).

The pattern and strobe sequence is selected for the particular
application. It need not be equal horizontally and vertically,
for example a pattern of six columns and four rows might be
selected. Also, for example, a pattern might have a center flash
point surrounded by three or more flash points and then possibly
surrounded by several more. An arrangement of concentric circles
with or without a central flash point might be useful. The
purpose of the pattern is to cover an area such that a subject
or subjects exposed to the strobing will be unable to move or at
least will have difficulty moving out of the pattern before
being incapacitated.

The flash pattern is cycled over a time period to repeat each
flash point at a rate sufficient to incapacitate a subject who
is in the pattern. It is known that flash rates from 7 15 Hz can
achieve incapacitating effects. A preferred range of flash rate
for incapacitating effect is 9 11 Hz. Therefore the strobe rate
is selected to cause each flash point to flash at the selected
rate.

It is not necessary that a specific flash point be directly
aimed at the subject's eyes, but at least some of the flash
points should be so closely directed to the subject's eyes as to
have the flash effect. Thus the flash pattern will be designed
in accordance with the type of use contemplated. Also a given
device could be equipped to allow selection of different flash
patterns for different uses.

In one exemplary use, for personal protection, a pattern
effective at a range of, say, 1 5 meters would be desirable. For
law enforcement purposes a pattern effective at a range from 5
10 meters would be desirable. For combat purposes a longer range
would be desirable. In each case the parameters of flash rate
and irradiance coupled with observed aperture, beam angle and
radiant aperture must be selected to enable incapacitation.

In some embodiments and applications it is desired or required
that incapacitation effects be obtained but without injury to
the subject's eyes. If incapacitation without injury (to the
eyes) is desired the irradiance level must not exceed the MPE.

In another aspect the invention is a method and apparatus in
which an array of light emitting elements or a single element
will cause incapacitation by applying a selected flash rate,
pulse duration and, for each flash, an optical power such that
at a particular range an irradiance level will be provided at a
particular range. In a further aspect, the irradiance is a
minimum of 1/260 of the MPE. Also, the range may be selected to
not exceed the MPE.

All the work and calculations that resulted in the data
presented in Table 1 was carried out under the guidance of the
safety standards developed by the Laser Institute of America
ANSI Z136.1-2000, Safe Use of Lasers [Ref 1]. This document
provided a number of rules that should be followed for the safe
use of high intensity light sources in particular, it contained
diagrams and formulas to define the maximum permissible exposure
(MPE), which provided the relationship between intensity of the
exposure, and the eye-damage threshold. Data from different
types of point and extended radiation sources, operating in
continuous and pulsed modes, is presented.

The focused LED modules and arrays are considered an extended
source of radiance. Such radiation source is defined as a source
viewed by the observer at an angle larger than .alpha..sub.min,
which is 1.5 mrad. The formula for calculating MPE.sub.pulses in
terms of source energy level for extended light sources is given
in Ref. [6], p. 46, Table 5b and Section 8.2.3. on page 37:

![](eq1b.jpg)

 where .tau. is the pulse duration or exposure time, n is the
number of pulses in the train, and C.sub.E=.alpha./.alpha..sub.min
when .alpha..sub.min.ltoreq..alpha..ltoreq..alpha..sub.max, and
where .alpha..sub.max is 100 mrad. .alpha. is aperture of the
device observed at the target plane. The LED results in Table 1
fall in this interval.

In terms of irradiance, for average pulse power, MPE:

![](eq1c.jpg)

where F is the frequency, and d is the pulse duty cycle. Since
only part of the energy reaches the human retina through the
iris in the eye (approximately 7 mm in diameter), the
MPE.sub.pulses must be reduced by a factor of 0.775. The final
formula is:

![](eq2.jpg)

It is well recognized that bright light flashing at frequencies
near the frequencies of the human brain (7 15 Hz) and operating
in the eye-safe region, are capable of affecting a person, or a
group of people, through visual impairment (green and blue-green
light are especially effective). The physiological and
psychological effects of these types of light are rapidly
induced and can range from simple glare and flashblindness to
strong startlement, vertigo and disorientation. The strongest
effects appear when the source intensity is at the level of the
MPE (but still in the safe region), and the effectiveness of the
visual impairment drops with the reduction of the intensity of
light. An attempt to classify the visual impairment effect in
accordance to the intensity of light for one exposure of 0.25
sec that is equal to the aversion time (blink effect) has been
made in Reference [2]. The diagram of FIG. 4 presented below
progressively shows the effects from very strong flashblindness
(which includes vertigo, disorientation and startlement) to
simple glare (right column) versus irradiance level on the eye
(left column). The strongest effects appeared when the
irradiance is on the level of MPE, which is 2.6 mW/cm.sup.2. The
arrow on the right pointing down indicates the decrease of the
effectiveness, as the exposure time diminishes.

At frequencies of 7 15 Hz, exposure duration of 0.25 sec is not
achievable. Therefore, a number of pulses should be applied to
accomplish incapacitating effect. As shown in Formula (2), MPE
and hence, the strongest effect, could be provided at any level
of irradiance by applying the respective number of pulses, while
maintaining the equivalence of the other parameters. There would
be more pulses at lower irradiance and vice versa. In turn, the
number of pulses will define the incapacitating time. To
estimate this time, the formula is rewritten as:

![](eq3.jpg)

.times..tau..times..times..times..times. ##EQU00005## and the
irradiance that was accomplished in the device is suggested as
the MPE. The number of pulses derived from (3) gives the
estimated time necessary to produce the highest level of the
incapacitating effect at a given irradiance, frequency, pulse
duration and the device design (C.sub.E).

The visual impairment that is produced by the intense flashing
light is a cumulative effect; therefore, the dosage of radiation
received depends on the number of pulses delivered.
Alternatively, in another way, as fewer pulses are delivered,
the MPE would be higher (see Formula 1). Hence, if one wants to
estimate the time necessary to produce visual impairment effect
at the level of irradiance lower than MPE, the number of pulses
in Formula 1 should be simply divided by the ratio of irradiance
produced by the device (which is considered as MPE) by the
irradiance, at which level the effect is considered:

![](eq4.jpg)

##EQU00007## (I.sub.MPE is the irradiation produce by the
devise, and I is the level of irradiance under consideration).
By substituting n in (1) for (4), the final formula (3) is
rewritten as

![](eq5.jpg)

For exemplary considerations, this formula was used to
calculate the time durations necessary to produce visual
impairment effects at levels equivalent to the single irradiance
exposure levels of 2.6, 1, 0.5, 0.1 and 0.01 mW/cm.sup.2 for a
given frequency of pulses. The value of A is 1, 2.6, 5.2, 26 and
260, respectively. These were selected for providing degrees of
incapacitation (A, B, C, D and E in Table 1).

Equation (5) establishes the relationship between the
irradiance on the target and the flash time, number of flashes
and the observed clear aperture of the device.

The results are presented in Table 1.

![](tbl1.jpg)  
![](tbl1a.jpg)

Parameters used during the testing and calculations: 19 LED
module: .tau.=0.015 sec; F=9 Hz; d=0.135. Testing distance 6
feet. 37 LED module: .tau.=0.011 sec; F=10 Hz; d=0.11. Testing
distance 6 feet.

Columns (from left to right) in the table represent:

Column1 lists the varying incapacitating physiological and
psychological effects produced due the visual impairment of
bright flashing light (A, B, C, D, and E). The effects are
classified in accordance to the diagram of FIG. X which is based
on broad range of experimental data (see reference E). Effects
are listed in the order from the strongest, A, that are caused
at the irradiance levels of MPE and progressively down to the
weaker introduced at lower levels of irradiance, B, C, D, and E.

Column 2 shows the irradiance levels of a single exposure of
0.25 sec, which introduce the respective effects according the
diagram in FIG. 5.

Column 3 and 4 shows the calculated time necessary to produce
different levels of incapacitating effects with two different
LED array configurations that were fabricated and tested. These
prototypes were operated in temporal pulsed mode. The parameters
of the pulse stated in the table and below the table was
actually measured. The measured irradiance produced by the pulse
was considered equal to the MPE, and the number of pulses that
produces incapacitating effect at this level (highest
permissible irradiance level) was calculated using Formula 3.
Formulas 4, and 5 were used to calculate the number of pulses,
which will produce effects of lower strength. The time was
calculated by dividing the number of pulses by the flash
frequency.

Columns 5 and 6 present the calculated incapacitating time of
two of many possible devices based on the 37LED array similar to
the presented in the column 4, but operating in the
multidirectional strobe mode. The parameters of the device
provide rapid incapacitating time and produce the strongest
level of visual impairment. The only difference between them in
the design is the observed aperture-6'' in one device and 4'' in
the second one. The other parameters used in the calculations
are: Operating distance-6 feet; beam divergency-5.degree.;
irradiance-233 mW/cm.sup.2 (calculated from the experimental
date for the divergence angle of 25.degree.; spot diameter at
working distance-0.524 feet; simultaneously covered
area-3.times.3 feet with 36 flashpoints; .tau.=0.004 sec; F=7
Hz; d=0.028. Note, that in the multidirectional strobe
arrangement the exposure time related to the flashing frequency
as 1/F times the number of flashpoints.

Referring to Table 1 it is first assumed that for a practical
apparatus and method of incapacitation, the effect must be
produced quickly, giving the target insufficient time to evade
the flashing (whether in by pattern, aimed or held steady).
Consequently only those entries in the table marked "rapid" are
regarded as effective for incapacitation. It is appreciated that
the columns 2, 3, 4, and 5 are constructed with reference to
selected values for the variables, and that other selected
combination of values would possibly extend the range of each
value. To the extent understood from Table 1, using an array of
at least about 19 LEDs incapacitation can be achieved with an
aperture at exit of about 4.6 in., incapacitation can be
achieved with an irradiance of at least about 4.9 mW/cm.sup.2.
As the aperture is closed as in column 5 to 5.degree. and
irradiance is increased to about 233 mW/cm.sup.2 a considerably
more severe level of incapacitation occurs. Applying the
variables incapacitation can be made to occur in a method and
apparatus as follows:

To reach a minimum irradiance of 1/260 of the MPE to cause
"rapid" incapacitation divide formula (2) by 260.

Both projected designs are feasible. They require only the beam
concentration in the smaller angle. Such nonimaging beamformers
for LED arrays applications were already computed down to
divergence angles of 2.degree.. A variety of alternative designs
are possible. They depend on the entry parameters, which are F,
the required area of coverage, and the operating distance. The
LED array could operate in the continuous and pulsed mode. In
the continuous mode the light flashing frequency is provided by
the predetermined spatial movement of the actuators. In the
pulsed mode the flashing frequency is provided by the
synchronous movement of the actuators and electronic control of
the LEDs light pulses. The pulse mode is preferable because the
LED could provide few times higher pulse power, compare to the
continuous mode. A simple range finder, or radiometer similar to
one used in the photo cameras to determine the exposure time
could be utilized to adjust the parameters of the device, such
as pulse duration, frequency and power, dependently at the
operational distance, in order to provide safe operation below
MPE.

**REFERENCES**

The content of the following references is incorporated by
reference into this description: 1. ANSI Z136.6-2000, American
National Standard for Safe Use of Lasers, Outdoor Lasers, New
York: The Laser Institute of America, 2000. 2. R. J. Rockwell,
Jr., W. J. Ertle, C. E. Moss, "Safety Recommendations of Laser
Pointers," Laser-Resources,
www.laser-resources.net/pointer-safety.htm, accessed Apr. 15,
2003.

Although the invention has been described with respect to
various embodiments, they are not intended to be exhaustive.
Many modifications and variations are possible in light of the
above teaching without departing from the scope of the claims
set out below. It is intended that the invention is to be
limited only to the full scope and coverage of the claims as
permitted under the Patent Law.

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