Title of Invention

ARTICLE SCREENING SYSTEM

Abstract During the last ten years patents directed to luggage scanning apparatus began to appear in ttie patent art. Absent from the variety of approaches in the art is stereoscopic imaging that entails exposing two ot more images of the same object each taken ixU a slightly different perspective. If the perspectives are too different that is if there is too much separation of the X-ray exposures, the image will look flat Yet withila slight separation, a stereo separation, interference occurs. Herein a system is provided for the production of stereo pairs. One perspective, a left or a right perspective angle, is first established. Next, the other perspective angle is computed Using these left and right perspective angle, is first established. Next, the other perspective angle is computed. Using these left and right perspectives the X-ray sources can then be spaced away from each other. Track 20 carries left X-ray camera 30 that supports X-ray source L through plate 22, and plate 24 supports X-ray camera 32l carrying X-ray tube R on the same track. For comparison with Fig. 2 common line 8 has been shown as a dashed line in Fig. 3. Likewise angles A and B have been included in Fig. 3 for the purpose of clarification. Thus, camera L is mounted to rriaintain the predetermined angle a, and X-ray device R is oriented to emit a collimaited -X-ray beam at the derived angle , both relative to the common line 8. Referring now in general to the operation of the system, for the sake of clarity it has been assumed that the conveyor is moving from left to right. Clearly if it is viewed as moving from right to left, the right perspective angle would be established first, and the left angle would be derived. Articles 36, such as luggage, parts being manufactured!! or other objects being scanned are transported by conveyor belt 37 driven in the usual manner by rollers 38 and 39 to transport the parcels through the collimated fan-shaped X-ray beams. Left sensor LS and %ht sensor RS are separately illuminated by the L and R X-ray sources respectively as the parcels pass between the X^l ray sources and the left and right sensors. It remains to identify and combine the irnage data from the left and right sensors.
Full Text FORM 2
THE PATENT ACT 1970 (39 of 1970)
The Patents Rules, 2003 PROVISIONAL COMPLETE SPECIFICATION See Section 10, and rule 13)
1. TITLE OF INVENTION
ARTICLE- SCREENING SYSTEM.-

2. APPLICANT(SI
a) Name
b) Nationality
b) Address'

UNITED STATES OF AMERICA AS REPRESENTED BY
THE ADMINISTRATOR OF THE NATIONAL AERONAUTICS
AND SPACE ADMINISTRATION
AMERICAN Company
3 00 E. STREET. SW,
WASHINGTON, DC 2 0546,
U.S.A.




PREMBLE TO THE DESCRIPTION

GRANTED
9-9-2006

The following specification particularly describes the invention and the manner in which it is to be performed :

1
ARTICLE SCREENING SYSTEM

CROSS-REFERENCES TO RELATED APPLICATIONS

There are no applications related to this application.
STATEMENT ii REGARDING FEDERALLY-SPONSORED RESEARCH OR

DEVELOPMENT

The invention described in this patent was made by an employee of the United

States Government and may be manufactured and used by or for the Government for governmental purposes without the payment of any royalties.
FIELD OF THE INVENTION

This invention | relates to screening apparatus particularly suited for screening
articles or object's such as assembly line parts and baggage.
,
BACKGROUND OF THE INVENTION

Considering first the baggage aspect, during the last ten years patents directed to
luggage inspecting apparatus began to appear in the patent art. Recently there has
been a significant increase in patents relating to luggage scanning, each with a
ii different approach. Illustrating these approaches, the invention that is the subject of
U. S. 5,247, 561 is based on Compton scattering. Compton scattering is proportional
to mass density.! Energy such as X-rays applied to luggage containers is measured,
and a three-dimensional image of the objects in the container is constructed. In U. S.
6,304, 629 a conveyor belt passes through an isolating tunnel which is a substantially
enclosed area ofjjthe runnel that is sealed-off by curtains so that no X-rays will leak
out. The X-ray baggage system disclosed in U. S.
6,088, 423 uses tloree parallel stationary beams of X-rays in an enclosed tunnel. The parallel rays are! spaced from each other in the runnel along the direction in which baggage moves through the tunnel.
2

The three fan beams produce sets of scan lines from which X-ray attenuation data are measured. The background section of that patent refers to various patents such as U. S. 5,796, 802, U. S. 6,256, 404, and U. S. 943, 388 directed to tomographically produced X-ray images. Computed X-ray tomography is a technique which has been in use in medical applications for more than 20 years. In U. S. 5,796, 802, in order to
save additional! time required in computed tomography, the, data are first only
il partially analyzed. From this pre-selected, pre-screened, data it is determined
whether a physical attribute of interest is present. In U. S. 5,943, 388 a plurality of X-
ray detectors, each having an output which includes at least two threshold data
levels, are utilized. Display means responsive to the plurality of X- ray detectors
produce tomographic images for different energy bands. In the computed
tomography system of U. S. 6,256, 404 the computed tomography machine scans the
field of view to generate scan data. Using the size and location of the scanned object
two portions of (pixels in the field of view are identified. Only pixels that provide
information related to the scanned object, the first portion of pixels, are processed
during image reconstruction.
A study of the different detection technologies in use today reveals that although the
use of a linear detector array allows a high inspection speed, its output signal does
Ii not provide sufficiently detailed information. A coherent X-RAY scatter spectra
analysis enables ;a better detection and much lower false alarm rate ( more time consuming, leading to a lower throughput. Dual energy detection systems
base their decision on an estimation of the density of objects in a bag or other
container. This is done by a combined evaluation of two different X-ray images
generated at two! different X-ray voltages (e. g. 150 kV and 75 kV). The approach
involves dedicated image processing to separate different objects superimposed on
one another in the projected image. The measured densities are compared with
i! library values of densities of known explosives. This multi-view technique uses two
X-ray systems with two different views (bottom view, top view). The estimated
I, material density lvalues generated from the two-projection image pixel data are
compared with the typical density data for identifying image objects.
3

It can be seen that the prior art illustrates the conclusion reached in U.. S. 6,088, 423 that existing baggage inspection systems meet some but not all of the inspection needs. Thus, three dimensional technologies are utilized but only as tomographic
and dual energy techniques. Absent from the variety of approaches discussed is
ii stereoscopic imaging technology. Rather than relying on shades or textures to
lj discover the shzjpe of an object, a more effective way would be to use two or more
images of the jsame object each taken from a slightly different perspective or
viewpoint. If there is too much separation or deviation of the x-ray tubes the image
will look flat. , jor the result may be a depth perception which is exaggerated or
reduced. Indeed, the stereo pairs may not fuse at all, with the viewer seeing two
separate images'J Yet with a slight separation interference occurs, possibly explaining
why stereoscopic systems have not been employed.
SUMMARY OF THE INVENTION
Stereo pairs create three dimensional images when binocular disparity cues are
correct.
Binocular disparity depends primarily on both the distance of the X-ray source to the
projection planejior target, and the separation of the right and left X-ray devices or
r tubes. In the case of X-ray scanning, when the binocular disparity is within correct
limits, the X-rays from the two X-ray tubes converge at the target. This convergence
results in cross .exposure interference, to be discussed hereinafter in more detail,
leading to blurrejd images. This is an undesirable condition which, as pointed out,
may have been the barrier to the stereo pairs approach to object scanning. Rather,
when multiple XHray sources have been used they have been orthogonal beam X-ray
|i systems in which X- ray beams were projected at right angles toward the top and a
side of an object.
An object of this invention is to provide a system for scanning articles such as luggage and other objects by the production of stereo pairs. Assuming that the articles are traveling from left to right, this is accomplished by the use of left and right X-ray tubes !aligned on a common line in the same plane above the path, and by
4

left and right X-ray sensors disposed below the path to sense X- rays emitted by the tubes. An appropriate, or desired, left viewpoint or perspective angle is first established, determined by the angle formed by the common line and a line to the target. Next, a right perspective angle is computed using the distance from the left X-ray tube to the Jtarget, the distance from the left X- ray tube to an imaginary point, and the distance from that imaginary point to the target. The imaginary point is a point which is within the stereoscopic range on the common line between the rubes.
The computed o'r determined right perspective angle, then, is a right viewpoint from
li a slightly different perspective leading to a stereo pair. Using these left and right
perspectives, or perspective angles, the left and right X-ray sources or tubes can then

be spaced away

from each other an actual distance such that the stereo base is

greater than a normal stereo base required for a stereo pair of images. This spacing
eliminates cross lexposure interference while still obtaining X-ray exposures from
i two slightly different perspectives. Since the articles are traveling on a conveyor belt,
or otherwise, from left to right the two images required for stereoscopic vision will
have been sensed in sequence, although they are out of order. To this end a sensor is
l| used to determine luggage belt positions further enabling an estimate of the
!l
coordinates of the luggage belt appearing in the center-of-view of the left and right
sensors. A processor then separately stores radiographic data for objects appearing
II within the field-of- view of each sensor along with the belt coordinates of the center-of-view for each sensor, respectively.
ij I,
I
The processor provides a continuous sequence of stereo images for stereographic
|l display by retrieving left and right radiographic images with similar belt coordinate
ii estimates for transmission to the stereo display device. A human operator upon
viewing the stereo radiographic pairs may control the belt motion and display
sequence to more closely examine or re-examine items through interaction with the
operator control interface panel.
j. DETAILED DESCRIPTION OF THE INVENTION
5

Normal stereoscopic vision depends essentially on the fact that each eye sees from a slightly different perspective. The key to producing a stereoscopic display, then, is getting a different perspective to each eye. Parallax is merely the apparent
I;
displacement of a viewed point that results from a change in the point of observation
ij or from relocation from one viewing spot to another. The brain uses the differing
parallax to determine distances to objects being viewed. This same effect lies at the
heart of viewing stereo pairs taken from two lateral positions. When the stereo pair
is properly positioned left-to-right and then viewed through a stereoscopic device
the eyes send a signal to the brain, which on further processing, creates a perception
of depth. It is this perception of depth that must be obtained herein to yield a three
dimensional effect.
i,
As indicated previously, the degree of the stereo effect depends on both the distance of the X- ray source to the projection plane or article, and the separation of the left and right X-ray sources. Too large a separation is very difficult to resolve and is known as hyperstereo. It is this separation of left and right X-ray sources which is of concern herein. However, in the case of X-ray devices required for scanning a separation less than the hyperstereo distance is too close. To illustrate this Fig. 1 is given. Referring to that figure, X-ray sources 1 and 2 are illustrated, along with
i;
objects 4, on conveyor belt 6. A sensor or detector 7 is disposed within conveyor 6. It can be seen that the rays leading from two properly spaced X-ray sources 1 and 2
cross each otherj' the result being cross exposure interference producing an
Ii undesirable result! For stereo image pairs the images must be constrained not to
overlap. By the practice of this invention stereo pairs can be used to obtain three

dimensional views is accomplished a

of articles being scanned. For a better understanding of how this specific embodiment of the invention will now be described in

conjunction with the accompanying drawings,


Specific Embodiment
Fig. 1 is a diagrammatic exemplification of cross exposure interference.
6

Fig. 2 is a diagrammatic representation showing how the left and right perspective
angles are derived.
Fig. 3 is a diagrammatic view illustrating a scanning system including left and right
X-ray sources so disposed that their stereo base is within the hyperstereo range.
Fig. 4 is a block diagram illustrating certain functional components rendering the
stereo scanning'system operational.
Fig. 5 is an isometric view of an exemplary embodiment of a stereoscopic scanning
device of the invention.
|! It has been previously explained that 3-D images require that a stereo pair of images
i, be sensed. In stereo pairs a different perspective to each eye is obtained if the
separation of the left and right X- ray sources is less than the standard distance. In
ji general the standard stereoscopic distance, or separation range, for two X-ray
sources is one-twentieth to one-fiftieth of the distance from the X- ray source to the
projection plane or object. However, when this separation or stereo base is
maintained, cross exposure interference results. It has also been noted that the left
(L) and right (R) X-ray emitting tubes must be aligned on a common line in the same
plane. Fig. 2 illustrates a method by which the right X- ray source can be separated
from the left source by more than the stereoscopic distance to avoid the interference.
Dashed line 8 represents the common line. The X- ray camera is represented as 10
with left tube L emitting X-rays 12 toward target 14 at a predetermined perspective
angle'a formed by common line 8 and X-ray path 12 to the target. Since the right X-
ray tube P2 will;not be within the stereo base, an imaginary point PI spaced on
common line 8 a known distance dl within the stereoscopic range is taken as a
reference point. The distance on X-ray path 16 from point PI to the target 14 is also
known. Using the! distance dl to PL, the distance on X-ray path 16 from point PI to
I. the target 14, and the distance 12 from the target to the left X-ray tube L, a right
perspective anglelfi can be determined. Angles a and £ are the necessary viewpoints
from slightly different perspectives leading to a stereo pair. Since this angle fi is
known X-ray tube R can be moved away on common line 8 any desired distance d2
to, say, a point P2 and the scanner can be used without cross exposure interference.

7
A system utilizing the approach discussed in conjunction with Fig. 2 is shown in Fig.
3. Track 20 carries left X-ray camera 30 that supports X-ray source L through plate
22, and plate 24! supports X- ray camera 32 carrying X-ray tube R on the same track.
i For comparisoniwith Fig. 2 common line 8 has been shown as a dashed line in Fig. 3.
Likewise angles1 A and B have been included in Fig. 3 for the purpose of clarification.
Thus, camera Liis mounted to maintain the predetermined angle a, and X-ray device
R is oriented to 'emit a collimated -X-ray beam at the derived angle both relative to
j the common line 8.
Referring now in general to the operation of the system, for the sake of clarity it has
been assumed that the conveyor is moving from left to right. Clearly if it is viewed as
II moving from right to left, the right perspective angle would be established first, and
the left angle ,Would be derived. Articles 36, such as luggage, parts being
manufactured, or other objects being scanned are transported by conveyor belt 37
driven in the usual manner by rollers 38 and 39 to transport the parcels through the
collimated fan-shaped X-ray beams. Left sensor LS and right sensor RS are
separately illuminated by the L and R X-ray sources respectively as the parcels pass
i between the X- ray sources and the left and right sensors. It remains to identify and
lj combine the image data from the left and right sensors as explained in conjunction
with Fig. 4. ::
In Fig. 4 conveyor 41 is similar to belts used on conventional luggage scanners except
ji that the belt herein carries an encoded strip, preferably on its edge, bearing indicia
for use in defining a coordinate, enabling a sensor 46 to read the position of the belt.
J] A coordinate defined along the circumference of the belt is read by position sensor
46. A left X-ray source 42 and left image sensor 43 are positioned above and below
the belt surface, respectively, at an angle necessary to meet the hyperstereo geometry
constraints of the!!apparatus as previously discussed. A right X-Ray source 44 and

sensor 45 are positioned at a location further down the belt away from left image sensor 43. The right X-ray source and sensor are similarly located above and below the belt at the negative angle with respect to a normal to the belt surface. As explained hereinbefore, this geometry is required to achieve, without cross-
8

interference, the formation of a 3D radiograph of objects placed on the belt. Position sensor 46 is placed adjacent to the belt so that the encoded strip provides a
continuous reading of the belt's position. The belt position data from position sensor
I: 46 are transmitted via path 46a to a primary controller 47. Primary controller 47 also
receives X-ray radiographic image data from left sensor 43, and from right sensor 45
via data paths 43a and 45a, respectively. Primary controller 47 is also connected to an
operator-controlled interface 49 via a data path 49a. Primary controller 47 is further
connected to a stereo-display device 48, which is observed by a human operator 50.
In addition, primary controller 47 is connected to the servomotor drive mechanism
53 by 53a, allowing it to control the roller and belt system 41. Functional control of
r all operational modes of the luggage scanner is under the control of the operator-controlled interface 49. The human-machine interface consists of this operator-controlled interface 49, and the stereo-display device 48. Various operating modes
can be initiated by human operator 50, using the operator- controlled interface 49.
i' Examples of such modes are: the primary operating mode; the initialization mode;

and the service mode all of which will now be described.

In the primary operating mode, luggage placed on moving belt 41 will usually move
Ii without slipping on the belt's surface. The left and right source and sensor pairs will
send a sequential set of images to primary controller 47. At the same time belt
position sensor 46; readings, which will correspond to the belt's position, will be used
to tag the left andjiright sensed data with the corresponding belt coordinate of a point
appearing in the icenter-of-view of each sensor. Since the centers-of-view of image

sensors 43 and 45; are fixed with respect to each other, and with respect to the belt position sensed by sensor 46, the center of view measurements are readily derived from the belt position sensor data. The left sensor image data, along with the center-of-view measurement in belt coordinates, is stored in a sequential data structure in primary controller 47. Similarly, the right sensor image data is stored for the right eye in a separate sequential data structure along with its center-of- view measurement. When a piece of luggage 51 placed on the moving belt traverses between the left X-ray source 42 and left sensor 43 as shown in the Fig. 4, the
9

radiographic image of the luggage along with the coordinate measurement of the
centers-of-view ;in the belt's reference frame are stored by primary controller 47. The
luggage then traverses the distance to the right X-ray source 44 and right image
i sensor 45 and a second image for the right eye is made of the luggage piece as it
passes into the field of view of the right system as shown at 52 in Fig. 4. The right X-
ray image data is stored, along with the coordinate measurement or reference frame
on belt 41, in primary controller 47. Since the luggage rarely moves without sliding
the coordinate measurement of a piece of luggage shown in position as 52 above

right sensor 45,
and the measurement at the left sensor in position as 51 will be the
same. By using the coordinate measurement, primary controller 47 thus provides the stereo display device 48 with a left and right image for each eye as previously discussed. This process runs continuously while the belt is in morion. Since all image
frame data is tagjged with the coordinate measurement, individual pieces of luggage
'j need not be sensed as a continuous process. In this embodiment the stereo pairs are
viewed by an operator on a display device 48 in the form of a monitor. Various other
viewing methods are available as will be described hereinafter. Based on the
operator's observations commands can be issued, for instance via 53a, and the
operator's control interface panel 49 to adjust or change the belt speed, or to stop and
reverse the image stream. The operator can also place the machine in other control
modes.
Turning now to the initialization mode, this mode is used to prepare the machine for
use and to customize the machine for the unique physiological characteristics of each
operator. Since stereo vision depends not only on two eyes but on the role played by
the brain, the ability to merge two perspectives into a single 3D image differs from
individual to individual. The primary function of the initialization mode, then, is to
provide adjustments of off-sets from the nominal hyperstereo geometry to allow for
an optimized condition for each operator. The initialization mode also allows the
setting of operator passwords. Upon powering up the system, or on changing
ti operators, the initialization mode will be invoked so that a positive identification of a
certified operator can be made, and so that the proper operator-specific parameters can be set.
10

The third mode; is the service mode. This mode provides for routine and diagnostic testing of the apparatus to insure proper operation and to perform preventive and
corrective maintenance offal subsystems.
Other Embodiments
In the specific embodiment illustrated a monitor and primary controller were used
for viewing a stereo pair. It is to be understood, however, that various means are
available which! I enable the brain to merge the two perspectives into one true 3D
image. Such means are widely available. Hence, except that they are essential for
viewing, they are not a part of this invention per se. Examples of such means are
devices which actually produce the image by themselves, glasses which merely
ji influence the way the user sees the image on a standard monitor, and special stereo-
3D software. Considering these three means in greater detail, examples of devices
li
which actually produce an image by themselves are VR-helmets and head mounted devices. These devices are basically wearable monitors. To allow stereoscopic vision there is a little LCD or CRT monitor for each eye. Consumer products like VFX-1, i-
glasses or Cybermaxx have two LCD monitors with an effective resolution of about
263x240 pixels each. In addition some of these helmets have a head tracker which
I replaces or complements keyboard, mouse or joystick input by head-movement. The
hard and softwar'e compatibility of these devices is good, since they do not need
special graphics-modes or driver software for stereoscopic vision, but they do
require drivers foij head tracking.i
Examples of glasses which just influence the way an image is seen on a standard monitor are Uquid crystal Shutterglasses and Shutter-Screens with polarization glasses. Shutterglasses and Shutter- Screens are used in conjunction with a normal cathode-ray-tube-monitor or-projector. The two images required for stereoscopic
vision are displayed on the standard monitor in turns. For a fraction of a second the
ji image dedicated to the left eye is displayed, after that the image for the right eye
jl appears for the same duration of time and so on. The job of the glasses is to prevent
i'
11
the left eye froiii seeing the image dedicated to the right eye and vice versa. To do this the light is blocked by an LCD-"Shutter".
This can be accomplished in two ways. One way is to place the shutter on the monitor and wa|tch it through passive, non-electronic, polarization glasses. The other
way is to build the shutters into the glasses. The highest software compatibility is
\ i between the gra'phics-board and the monitor. There are several graphics boards with
ii
integrated glasses controllers. Other SHUTTERGLASSES are linked to the software.
Ii It can thus be seen that various alternatives are available for viewing the stereo pairs
j!
produced by this invention.
I
In the light of the foregoing description of the invention modifications will occur to
i those in the art; As an example it can be seen that in addition to luggage the
invention can be used for detecting contraband in schools, government building
security, airport; hand parcels, industrial processing applications, and even in
i; hospitals. As another modification, to insure that the luggage does not slide, the
ii conveyor belt can be provided with ribs, ridges, or dividers and the like. In addition,
whereas the sensors are shown within the conveyor belt in Fig. 3 the X-ray beam
angles can be adjusted so that the sensors can be placed at each end of the conveyor
i1 so that the conveyor will not receive X-ray radiation.
As still another variation, one structural form the invention is illustrated in Fig. 5. In that figure a housing 60 is provided in the form of a runnel having a curtain 62 in the form of straps, and turrets 64 and 66 housing X-ray cameras 30 and 32. Housing 68
LI
serves as an enclosure for the electronics described in conjunction with Fig. 4. Clearly the invention can be incorporated in any structure, or even in an open setup rather than the 'housing structure depicted in Fig. 5. Such ramifications and modifications are (deemed to be within the scope of this invention.
12

We Claim:
1. An X-ray-based imaging system providing stereoscopic three-dimensional
images cjf objects moving from left to right in a path beneath two X-ray
emitting!tubes, the system including: left and right X-ray tubes aligned on a
common) line in the same plane above the path; left and right X-ray sensors
l disposed|: below the path in alignment with the X-ray tubes to sense X-rays
emitted by the tubes; a left X-ray tube support adapted to constrain the left X-
ray tube I in a position a known distance from a target and at a known
perspective, the perspective being an angle formed by the common line and a
line to the target, permitting the left X-ray tube to emit a collimated X-ray
beam at ait angle which is a left viewpoint; computing means for determining
a right perspective angle, using the distance from the left X-ray tube to the
target, the; distance from the left X-ray tube to an imaginary point, and the
distance from the imaginary point to the target, the imaginary point being a
point which is within the stereoscopic range on the common line between the
tubes, the j determined right perspective angle being a right viewpoint from a
slightly different perspective leading to a stereo pair; a right X-ray tube
support adapted to retain the right X-ray tube on the common line in its
angular orientation to retain its determined right perspective angle, but
i; spaced away from the left X-ray tube an actual distance or stereo base greater
than normal stereo base to eliminate cross exposure interference while still
i[ obtaining X-ray exposures from two slightly different perspectives; means
!; operating the X-ray sources continuously; a discriminator adapted to sample
radiographic images sensed by the left sensor and to distinguish separate
objects passing over the sensor; a processor adapted to store separately
i! radiographic data for each object sensed by the left sensor; an encoder
i' adapted to!' sense conveyor positions of each object, to match the stored
radiographic data from the left sensor with corresponding radiographic data
sensed by |the right sensor, and to combine the matched left and right
radiographic data to form the stereo pair for three-dimensional viewing.
l ■
13

2. The X-ray-based imaging system of claim 1 wherein the discriminator
includes a conveyor belt carrying an encoded strip bearing indicia for use in
definingj :a coordinate in the belt's reference frame, a position sensor adapted
to read the coordinate, and an encoder adapted to derive a belt position from
ii the coordinate.
3. The X-ray-based imaging system of claim 2 wherein the processor is a
primary controller adapted to store right and left sensed radiographic image
data aong with the coordinate, and to provide a stereo pair for a viewing
means.
i ■ ■ •
4. The X-ray-based imaging system of claim 3 wherein the viewing means is a
!! device which produces the stereo image by itself.
5. The X-rayj-based imaging system of claim 3 wherein the viewing means is a pair of glasses which influences the way a user sees the image.
6. The X-ray-lbased imaging system of claim 3 wherein the viewing means is a standard monitor along with special stereo-3D software.
Dated thisfl4th day of February, 2005.

HIRAL CHANDRAKANT JOSHI /AGENT FOR UNITED STATES OF AMERICA AS REPRESENTED BY THE ADMINISTRATOR OF THE NATIONAL AERONAUTICS AND SPACE ADMINISTRATION

Documents:

135-mumnp-2005-abstract(9-9-2006).doc

135-mumnp-2005-abstract(9-9-2006).pdf

135-mumnp-2005-cancelled pages(9-9-2006).pdf

135-mumnp-2005-claims(granted)-(9-9-2006).doc

135-mumnp-2005-claims(granted)-(9-9-2006).pdf

135-mumnp-2005-correspondence(7-9-2006).pdf

135-mumnp-2005-correspondence(ipo)-(16-8-2007).pdf

135-mumnp-2005-drawing(9-9-2006).pdf

135-mumnp-2005-form 1(15-2-2005).pdf

135-mumnp-2005-form 18(15-2-2005).pdf

135-mumnp-2005-form 2(granted)-(9-9-2006).doc

135-mumnp-2005-form 2(granted)-(9-9-2006).pdf

135-mumnp-2005-form 3(14-2-2005).pdf

135-mumnp-2005-form 5(9-9-2006).pdf

135-mumnp-2005-form-pct-isa-210(15-2-2005).pdf

abstract1.jpg


Patent Number 208899
Indian Patent Application Number 135/MUMNP/2005
PG Journal Number 35/2007
Publication Date 31-Aug-2007
Grant Date 16-Aug-2007
Date of Filing 15-Feb-2005
Name of Patentee UNITED STATES OF AMERICA AS REPRESENTED BY THE ADMINISTRATOR OF THE NATIONAL AERONAUTICS AND SPACE ADMINISTRATION (NASA)
Applicant Address HIRAL CHANDRAKANT JOSHI CHANDRAKANT M. JOSHI PATENT & TRAE MARK ATTORNEYS 501, "VISHAWNANAK", CHAKALA ROAD ANDHERI (EAST) MUMBAI-400 099
Inventors:
# Inventor's Name Inventor's Address
1 FERNANDEZ, KENNETH, R. 2962 HAMPTON COVE WAY, HAMPTON COVE, AL 35763
PCT International Classification Number H05G 1/61
PCT International Application Number PCT/US03/26841
PCT International Filing date 2003-08-29
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 10/232, 937 2002-08-30 U.S.A.