WO1999045751A1 - Radiation transmission system - Google Patents

Radiation transmission system Download PDF

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Publication number
WO1999045751A1
WO1999045751A1 PCT/GB1999/000662 GB9900662W WO9945751A1 WO 1999045751 A1 WO1999045751 A1 WO 1999045751A1 GB 9900662 W GB9900662 W GB 9900662W WO 9945751 A1 WO9945751 A1 WO 9945751A1
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WO
WIPO (PCT)
Prior art keywords
conductive
reflective
fixed
centrally perforated
plane
Prior art date
Application number
PCT/GB1999/000662
Other languages
French (fr)
Inventor
Anthony Norman Patterson-Moutray
Original Assignee
Patterson Moutray Anthony Norm
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Patterson Moutray Anthony Norm filed Critical Patterson Moutray Anthony Norm
Priority to AU32659/99A priority Critical patent/AU3265999A/en
Publication of WO1999045751A1 publication Critical patent/WO1999045751A1/en

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Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q13/00Waveguide horns or mouths; Slot antennas; Leaky-waveguide antennas; Equivalent structures causing radiation along the transmission path of a guided wave
    • H01Q13/02Waveguide horns
    • H01Q13/0208Corrugated horns
    • GPHYSICS
    • G21NUCLEAR PHYSICS; NUCLEAR ENGINEERING
    • G21KTECHNIQUES FOR HANDLING PARTICLES OR IONISING RADIATION NOT OTHERWISE PROVIDED FOR; IRRADIATION DEVICES; GAMMA RAY OR X-RAY MICROSCOPES
    • G21K1/00Arrangements for handling particles or ionising radiation, e.g. focusing or moderating
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05HPLASMA TECHNIQUE; PRODUCTION OF ACCELERATED ELECTRICALLY-CHARGED PARTICLES OR OF NEUTRONS; PRODUCTION OR ACCELERATION OF NEUTRAL MOLECULAR OR ATOMIC BEAMS
    • H05H15/00Methods or devices for acceleration of charged particles not otherwise provided for, e.g. wakefield accelerators
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05HPLASMA TECHNIQUE; PRODUCTION OF ACCELERATED ELECTRICALLY-CHARGED PARTICLES OR OF NEUTRONS; PRODUCTION OR ACCELERATION OF NEUTRAL MOLECULAR OR ATOMIC BEAMS
    • H05H7/00Details of devices of the types covered by groups H05H9/00, H05H11/00, H05H13/00
    • H05H7/14Vacuum chambers
    • H05H7/18Cavities; Resonators

Definitions

  • This invention relates to the field of rapid electro-magnetic radiation utilisation.
  • Rapid electro-magnetic radiation solutions concern the transmission of signals between distances in less time than the time taken by light to travel the same distance. This has previously been achieved by multiple internal reflection in cylinders, known as 'tunnels'.
  • Objects of this invention are to provide decreases in transmission time by large factors, whilst reducing distortion and allowing variation in output in an assembly, the utility of this invention being related to reducing communication loops in space exploration, telemetry, detection, computer technology, fabrication and medicine.
  • This invention is divided into devices,stages,components,sub- components, devices being the combination in series of stages, each stage incorporating the use of electro-kinetic deflection in component pairs, each component being either electro-kinetic, convergent, divergent or reflective, sub-components as specified.
  • this invention provides various configurations of device, incorporating stages, components, and sub-components, the components being centrally perforated plane disc non-conductive reflective fixed thereon near circular conductive circuit at resistance within this baffle vane of plane cylinder perpendicular internal angular external sum ⁇ 180 s non-conductive reflective both concentric to central perforation , centrally perforated plane disc non-conductive reflective fixed thereon multiple circular conductive circuit in parallel at resistance within this multiple baffle of cylinder angular internal and angular external sum 2 ⁇ 180 a non-conductive reflective all concentric to central perforation , centrally perforated plane disc non-conductive reflective fixed thereon spiral conductive circuit at resistance within this multiple baffle of plane spiral internal and external angular vanes sum ⁇ 180 s reflective , centrally perforated plane disc non-conductive reflective fixed thereon elliptical conductive circuit at resistance within this baffle of elliptical non- conductive reflective cylinder external angular internal perpendicular sum ⁇ 180 2 non-conductive reflective perfor
  • a typical device will involve a number of stages, connected 9 together by some means of securely combining stages (50) such as fixing rod grooves (length E) cut perpendicularly at separation (length s) non- conductive non-reflective or ( where E equals length of disc edge, s equals separation of components) or casing.
  • stages such as fixing rod grooves (length E) cut perpendicularly at separation (length s) non- conductive non-reflective or (where E equals length of disc edge, s equals separation of components) or casing.
  • the device will commence with signal generator (47,48 or 49), and at intervals between a series of electro-kinetic stages will be positioned null disc (46) in order to reduce interference.
  • Convergent or divergent arrangements 52 or 53 could be positioned as intermediate stages and at the extreme end of the assembly.
  • a hybrid device will incorporate a signal generator (47,48 or 49) , electro-kinetic direct and/or reflective stages and convex reflective surfaces (components 38 to 45 inclusive), connected by some means of securely combining stages (50) such as fixing rod grooves (length E) cut perpendicularly at separation (length s) non-conductive non-reflective or ( where E equals length of disc edge, s equals separation of components) or casing.
  • Secondary devices would be positioned at some angle to the signal path , supported independently by some means of aligning a series of stages at some angle (51) such as a strut with rectangular base supporting two pairs of perpendicular rigid poles between which fixed at intervals (s) cylindrical tubing parallel to base (where s equals separation of components) , commencing with regularly emitting signal generator (47,48 or 49) presenting an output signal in alignment with convex reflective surfaces (components 38 to 45 inclusive).
  • Convergent or divergent arrangements (components 52 or 53) could be positioned intermediately and at the extreme end of the primary assembly.
  • the arrow demonstrates the signal path, the reflective surface illustrated is component 33, where gradient at distance r' from edge of surface radius r equals 1/ (tan (180 2 - (90 2 - (tan(-l) (r'/s)) 12 ) - (tan(-l) ((r-r') / (s-r'))) / 2)) being interchangeable with components 29,30,31,32, 34, 35, 36, 37, 38, 39, 40, 41, 42,43,44,45 combined with circuit component 27, being interchangeable with components 16,17,19,20,21,22,

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  • Physics & Mathematics (AREA)
  • Engineering & Computer Science (AREA)
  • Spectroscopy & Molecular Physics (AREA)
  • Plasma & Fusion (AREA)
  • General Engineering & Computer Science (AREA)
  • High Energy & Nuclear Physics (AREA)
  • Analysing Materials By The Use Of Radiation (AREA)

Abstract

The invention enables through directing radiation emission and a process of deflection (electro-kinetic deflection) the acceleration of a core signal. It consists of a system of components which may be variously combined to achieve properties in velocity, amplitude, divergency and distortion reduction, in order primarily to reduce conversation loops in space exploration. Acceleration is achieved by each turn (105) of the emitting circuit. The output characteristics are variable as electrical parameters are changed and components are switched on and off. A lateral form of the device allows higher acceleration whilst reducing phasing difficulties.

Description

1 RADIATION TRANSMISSION SYSTEM
This invention relates to the field of rapid electro-magnetic radiation utilisation.
Rapid electro-magnetic radiation solutions concern the transmission of signals between distances in less time than the time taken by light to travel the same distance. This has previously been achieved by multiple internal reflection in cylinders, known as 'tunnels'.
However 'tunnels' have only decreased transmission time by small factors, incur severe distortion and cannot vary their output.
Objects of this invention are to provide decreases in transmission time by large factors, whilst reducing distortion and allowing variation in output in an assembly, the utility of this invention being related to reducing communication loops in space exploration, telemetry, detection, computer technology, fabrication and medicine.
This invention is divided into devices,stages,components,sub- components, devices being the combination in series of stages, each stage incorporating the use of electro-kinetic deflection in component pairs, each component being either electro-kinetic, convergent, divergent or reflective, sub-components as specified.
Accordingly, this invention provides various configurations of device, incorporating stages, components, and sub-components, the components being centrally perforated plane disc non-conductive reflective fixed thereon near circular conductive circuit at resistance within this baffle vane of plane cylinder perpendicular internal angular external sum < 180s non-conductive reflective both concentric to central perforation , centrally perforated plane disc non-conductive reflective fixed thereon multiple circular conductive circuit in parallel at resistance within this multiple baffle of cylinder angular internal and angular external sum 2 < 180a non-conductive reflective all concentric to central perforation , centrally perforated plane disc non-conductive reflective fixed thereon spiral conductive circuit at resistance within this multiple baffle of plane spiral internal and external angular vanes sum < 180s reflective , centrally perforated plane disc non-conductive reflective fixed thereon elliptical conductive circuit at resistance within this baffle of elliptical non- conductive reflective cylinder external angular internal perpendicular sum <1802 non-conductive reflective perforation central to each , centrally perforated plane disc non-conductive reflective fixed thereon multiple elliptical conductive circuit in parallel at resistance within these baffle vanes of elliptical cylinder internal and external angular sum <180e perforation central to all , centrally perforated plane disc non-conductive reflective fixed thereon segmented circular (switchable) circuit in parallel at resistance within these baffle vane segments of plane cylinder angular external perpendicular internal non-conductive reflective all concentric to central perforation , centrally perforated plane disc non-conductive reflective fixed thereon multiple concentric segmented circular (switchable) circuit in parallel at resistance within these equal number baffle vane segments of plane cylinder angular internal angular external cone ( or cylinder) non-conductive reflective all concentric to central perforation , centrally perforated plane disc non-conductive non -reflective fixed thereon near circular conductive circuit at resistance within this baffle vane of plane cylinder perpendicular internal angular external sum
< 180s non-conductive reflective both concentric to central perforation , centrally perforated plane disc non-conductive non -reflective fixed thereon multiple circular conductive circuit in parallel at resistance within this multiple baffle of cylinder angular internal and angular external sum
< 180s non-conductive reflective all concentric to central perforation , centrally perforated plane disc non-conductive non-reflective fixed thereon 3 spiral conductive circuit at resistance within this multiple baffle of plane spiral internal and external angular vanes sum < 1802 reflective , centrally perforated plane disc non-conductive non -reflective fixed thereon elliptical conductive circuit at resistance within this baffle of elliptical non- conductive reflective elliptical cylinder external angular internal perpendicular sum <180s non-conductive reflective perforation central to each , centrally perforated plane disc non-conductive non -reflective fixed thereon multiple elliptical conductive circuit in parallel at resistance within these baffle vanes of elliptical cylinder internal and external angular sum <180e perforation central to all , centrally perforated plane disc non- conductive non -reflective fixed thereon segmented circular (switchable) circuit in parallel at resistance within these baffle vane segments of plane cylinder angular external perpendicular internal non-conductive reflective all concentric to central perforation , centrally perforated plane disc non- conductive non -reflective fixed thereon multiple concentric segmented circular (switchable) circuit in parallel at resistance within these equal number baffle vane segments of plane cylinder angular internal angular external perpendicular non-conductive reflective all concentric to central perforation , centrally perforated plane disc non-conductive reflective fixed thereon plane cylinder non-conductive non-reflective within which fixed short sections of cone lesser internal angle non-conductive reflective at intervals along length in the recesses formed being fixed multiple circular conductive circuit in parallel at resistance , centrally perforated plane disc non-conductive non-reflective fixed thereon plane cylinder non- conductive non-reflective within which fixed short sections of cone lesser internal angle non-conductive reflective at intervals along length in the recesses formed being fixed multiple circular conductive circuit in parallel at resistance within this fixed plane cylinder non-conductive reflective at separation, centrally perforated plane disc non-conductive non-reflective 4 fixed thereon plane cylinder non-conductive reflective without which fixed short sections of cone lesser external angle non-conductive reflective at intervals along length in the recesses formed being fixed multiple circular conductive circuit in parallel at resistance being within at separation plane cylinder non-conductive reflective , centrally perforated plane disc non-conductive reflective fixed thereon plane cylinder non-conductive non-reflective within which fixed spiral cylinder lesser internal angle non- conductive reflective along length in the recesses formed being fixed spiral conductive circuit in parallel at resistance , centrally perforated plane disc non-conductive non-reflective fixed thereon plane cylinder non-conductive non-reflective within which fixed spiral cylinder lesser internal angle non- conductive reflective along length in the recesses formed being fixed spiral conductive circuit in parallel at resistance within this fixed plane cylinder non-conductive reflective at separation , centrally perforated plane disc non-conductive non-reflective fixed thereon plane cylinder non-conductive reflective without which fixed spiral cylinder lesser external angle non- conductive reflective along length in the recesses formed being fixed spiral conductive circuit at resistance being within at separation plane cylinder non-conductive reflective , centrally perforated plane disc non-conductive non-reflective fixed thereon cone lesser internal angle non-conductive reflective without which fixed short sections of plane cylinder non- conductive reflective at intervals along length in the recesses formed being fixed multiple circular conductive circuit in parallel at resistance being within at separation plane cylinder non-conductive reflective , centrally perforated plane disc non-conductive non-reflective fixed thereon cone lesser internal angle non-conductive reflective without which fixed spiral cone perpendicular vanes non-conductive reflective along length in the recesses formed being fixed spiral conductive circuit at resistance being within at separation plane cylinder non-conductive reflective , centrally 5 perforated plane disc non-conductive reflective fixed thereon cone lesser external angle non-conductive non-reflective within which fixed short sections of cone lesser internal angle non-conductive reflective at intervals along length in the recesses formed being fixed multiple circular conductive circuit in parallel at resistance , centrally perforated plane disc non-conductive non-reflective fixed thereon cone lesser external angle non- conductive non-reflective within which fixed short sections of cone lesser internal angle non-conductive reflective at intervals along length in the recesses formed being fixed multiple circular conductive circuit in parallel at resistance within this fixed plane cylinder non-conductive reflective at separation, centrally perforated plane disc non-conductive non-reflective fixed thereon cone lesser internal angle non-conductive reflective without which fixed short sections of plane cylinder non-conductive reflective at intervals along length in the recesses formed being fixed multiple circular conductive circuit in parallel at resistance being within at separation plane cylinder non-conductive reflective , centrally perforated plane disc non-conductive reflective fixed thereon cone lesser external angle non- conductive non-reflective within which fixed spiral lesser internal angle cone angular vanes non-conductive reflective along length in the recesses formed being fixed spiral conductive circuit at resistance , centrally perforated plane disc non-conductive non-reflective fixed thereon cone lesser external angle non-conductive non-reflective within which fixed spiral lesser internal angle cone angular vanes non-conductive reflective along length in the recesses formed being fixed spiral conductive circuit at resistance within this fixed plane cylinder non-conductive reflective , centrally perforated plane disc non-conductive non-reflective fixed thereon cone lesser internal angle non-conductive reflective without which fixed spiral lesser angle cone perpendicular vanes non-conductive reflective along length in the recesses formed being fixed spiral conductive circuit at resistance being within at separation plane cylinder non-conductive reflective , centrally perforated plane disc non-conductive non-reflective fixed whereon centrally perforated plane reflective surface, centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated concave reflective surface where on gradient is constant across its surface , centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated concave reflective surface where on gradient has two constituents each over a fraction of its radius , centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated concave reflective surface where on gradient falls evenly towards its centre , centrally perforated plane disc non- conductive non-reflective fixed on which centrally perforated concave reflective surface where on gradient falls decreasingly towards its centre , centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated concave reflective surface where on gradient falls increasingly towards its centre , centrally perforated plane disc non- conductive non-reflective fixed on which centrally perforated concave reflective surface where on gradient rises evenly towards its centre , centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated concave reflective surface where on gradient rises increasingly towards its centre, centrally perforated plane disc non- conductive non-reflective fixed on which centrally perforated concave reflective surface where on gradient rises decreasingly towards its centre, centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated convex reflective surface where on gradient is constant across its surface , centrally perforated plane disc non- conductive non-reflective fixed on which centrally perforated convex reflective surface where on gradient has two constituents each over a fraction of its radius , centrally perforated plane disc non-conductive non- 7 reflective fixed on which centrally perforated convex reflective surface where on gradient falls evenly towards its centre , centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated convex reflective surface where on gradient falls decreasingly towards its centre , centrally perforated plane disc non-conductive non- reflective fixed on which centrally perforated convex reflective surface where on gradient falls increasingly towards its centre , centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated convex reflective surface where on gradient rises evenly towards its centre , centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated convex reflective surface where on gradient rises increasingly towards its centre , centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated convex reflective surface where on gradient rises decreasingly towards its centre, centrally perforated (radius z) plane (from radius (x) to (x-E)) constant gradient (gradient equals (s/x) (from radius (x- E- to (z)) reflective disc(radius x) (where E equals length of disc edge), plane disc non-conductive non-reflective where on two lengths of encased non-emitting cable forming circuit with solid cylinder plane surface conductor at centre of disc , plane disc non-conductive non-reflective where on two lengths of encased non-emitting cable forming circuit with solid cylinder concave surface conductor at centre of disc , plane disc non- conductive non-reflective where on two lengths of encased non-emitting cable forming circuit with solid cylinder convex surface conductor at centre of disc, means of securely combining stages, means of aligning a series of stages at some angle, centrally perforated plane disc reflective fixed thereon divergent arrangement , centrally perforated plane disc reflective fixed thereon convergent arrangement , centrally perforated plane disc non-conductive reflective fixed thereon elliptical conductive 8 circuit at resistance within this baffle of elliptical non-conductive reflective cylinder external angular internal perpendicular sum <180δ non-conductive reflective perforation not central to each , centrally perforated plane disc non-conductive reflective fixed thereon multiple elliptical conductive circuit in parallel at resistance within these baffle vanes of elliptical cylinder internal and external angular sum <180s perforation not central to all , centrally perforated plane disc non- conductive non -reflective fixed thereon elliptical conductive circuit at resistance within this baffle of elliptical non-conductive reflective elliptical cylinder external angular internal perpendicular sum <180s non- conductive reflective perforation not central to each , centrally perforated plane disc non-conductive non -reflective fixed thereon multiple elliptical conductive circuit in parallel at resistance within these baffle vanes of elliptical cylinder internal and external angular sum <180- perforation not central to all.
By way of a specific embodiment of the invention , the general structure of a device, a categorisation of its stages and illustration of each component (numbered as listed) will now be described with reference to the accompanying drawings: Figure 1 General form of device Figure 2 General form of hybrid device
Figure 3 Example ( component 2) of plane circuit direct path Stage Figure 4 Example ( Components 32, 9 ) of plane circuit reflected path Stage
Figure 5 Example ( Component 23 ) of cylinder circuit direct path Stage Figure 6 Example ( Components 33, 27 ) of cylinder circuit reflected path Stage
A typical device (fig 1) will involve a number of stages, connected 9 together by some means of securely combining stages (50) such as fixing rod grooves (length E) cut perpendicularly at separation (length s) non- conductive non-reflective or ( where E equals length of disc edge, s equals separation of components) or casing. The device will commence with signal generator (47,48 or 49), and at intervals between a series of electro-kinetic stages will be positioned null disc (46) in order to reduce interference. Convergent or divergent arrangements (52 or 53) could be positioned as intermediate stages and at the extreme end of the assembly.
A hybrid device (fig 2) will incorporate a signal generator (47,48 or 49) , electro-kinetic direct and/or reflective stages and convex reflective surfaces (components 38 to 45 inclusive), connected by some means of securely combining stages (50) such as fixing rod grooves (length E) cut perpendicularly at separation (length s) non-conductive non-reflective or ( where E equals length of disc edge, s equals separation of components) or casing. Secondary devices would be positioned at some angle to the signal path , supported independently by some means of aligning a series of stages at some angle (51) such as a strut with rectangular base supporting two pairs of perpendicular rigid poles between which fixed at intervals (s) cylindrical tubing parallel to base ( where s equals separation of components) , commencing with regularly emitting signal generator (47,48 or 49) presenting an output signal in alignment with convex reflective surfaces (components 38 to 45 inclusive). Convergent or divergent arrangements (components 52 or 53) could be positioned intermediately and at the extreme end of the primary assembly.
To correctly orientate and combine components to produce stages for assembly into a device (fig 1, fig 2) , it is necessary to identify six categories of stage , which include: direct path plane circuit (fig 3) ; reflected path plane circuit (fig 4) ; direct path cylindrical circuit (fig 5) ; reflected path cylindrical circuit (fig 6) ; signal generator; null disc. 10 In fig 3, the arrow demonstrates the signal path, component 2 being illustrated but interchangeable with components 1,3,4,5,6,7,54,55. In fig 4 , again the arrow demonstrates the signal path , the reflective surface illustrated being component 32, (a sphere with radius equal to (s) where s equals separation of components), interchangeable with components 29, 30, 31, 33, 34, 35, 36, 37,38,39,40,41,42,43,44,45, combined with circuit component 9, being interchangeable with components 8,10,11,12,13,14, 56,57. In fig 5, once more the arrow demonstrates the signal path, component 23 being illustrated but interchangeable with components
15.18.27. In fig 6, the arrow demonstrates the signal path, the reflective surface illustrated is component 33, where gradient at distance r' from edge of surface radius r equals 1/ (tan (1802 - (902 - (tan(-l) (r'/s)) 12 ) - (tan(-l) ((r-r') / (s-r'))) / 2)) being interchangeable with components 29,30,31,32, 34, 35, 36, 37, 38, 39, 40, 41, 42,43,44,45 combined with circuit component 27, being interchangeable with components 16,17,19,20,21,22,
24.25.28. Components would be joined where necessary by some means of coupling components (not shown) such as screws, rivets or clips. Each stage , when assembled, is connected so that the signal path lies in one direction.

Claims

11 CLAIMS 1. A radiation transmission system comprising a centrally perforated plane disc non-conductive reflective fixed thereon near circular conductive circuit at resistance within this baffle vane of plane cylinder perpendicular internal angular external sum < 1802 non-conductive reflective both concentric to central perforation , centrally perforated plane disc non- conductive reflective fixed thereon multiple circular conductive circuit in parallel at resistance within this multiple baffle of cylinder angular internal and angular external sum < 180s non-conductive reflective all concentric to central perforation , centrally perforated plane disc non- conductive reflective fixed thereon spiral conductive circuit at resistance within this multiple baffle of plane spiral internal and external angular vanes sum < 1802 reflective , centrally perforated plane disc non- conductive reflective fixed thereon elliptical conductive circuit at resistance within this baffle of elliptical non-conductive reflective cylinder external angular internal perpendicular sum <1802 non-conductive reflective perforation central to each , centrally perforated plane disc non- conductive reflective fixed thereon multiple elliptical conductive circuit in parallel at resistance within these baffle vanes of elliptical cylinder internal and external angular sum <180s perforation central to all , centrally perforated plane disc non-conductive reflective fixed thereon segmented circular (switchable) circuit in parallel at resistance within these baffle vane segments of plane cylinder angular external perpendicular internal non-conductive reflective all concentric to central perforation , centrally perforated plane disc non-conductive reflective fixed thereon multiple concentric segmented circular (switchable) circuit in parallel at resistance within these equal number baffle vane segments of plane cylinder angular internal angular external cone ( or cylinder) non- conductive reflective all concentric to central perforation , centrally 12 perforated plane disc non-conductive non -reflective fixed thereon near circular conductive circuit at resistance within this baffle vane of plane cylinder perpendicular internal angular external sum < 180s non- conductive reflective both concentric to central perforation , centrally perforated plane disc non-conductive non -reflective fixed thereon multiple circular conductive circuit in parallel at resistance within this multiple baffle of cylinder angular internal and angular external sum < 1802 non- conductive reflective all concentric to central perforation , centrally perforated plane disc non-conductive non-reflective fixed thereon spiral conductive circuit at resistance within this multiple baffle of plane spiral internal and external angular vanes sum < 1802 reflective , centrally perforated plane disc non-conductive non -reflective fixed thereon elliptical conductive circuit at resistance within this baffle of elliptical non- conductive reflective elliptical cylinder external angular internal perpendicular sum <1802 non-conductive reflective perforation central to each , centrally perforated plane disc non-conductive non -reflective fixed thereon multiple elliptical conductive circuit in parallel at resistance within these baffle vanes of elliptical cylinder internal and external angular sum <180s perforation central to all , centrally perforated plane disc non- conductive non -reflective fixed thereon segmented circular (switchable) circuit in parallel at resistance within these baffle vane segments of plane cylinder angular external perpendicular internal non-conductive reflective all concentric to central perforation , centrally perforated plane disc non- conductive non -reflective fixed thereon multiple concentric segmented circular (switchable) circuit in parallel at resistance within these equal number baffle vane segments of plane cylinder angular internal angular external perpendicular non-conductive reflective all concentric to central perforation , centrally perforated plane disc non-conductive reflective fixed thereon plane cylinder non-conductive non-reflective within which 13 fixed short sections of cone lesser internal angle non-conductive reflective at intervals along length in the recesses formed being fixed multiple circular conductive circuit in parallel at resistance , centrally perforated plane disc non-conductive non-reflective fixed thereon plane cylinder non- conductive non-reflective within which fixed short sections of cone lesser internal angle non-conductive reflective at intervals along length in the recesses formed being fixed multiple circular conductive circuit in parallel at resistance within this fixed plane cylinder non-conductive reflective at separation, centrally perforated plane disc non-conductive non-reflective fixed thereon plane cylinder non-conductive reflective without which fixed short sections of cone lesser external angle non-conductive reflective at intervals along length in the recesses formed being fixed multiple circular conductive circuit in parallel at resistance being within at separation plane cylinder non-conductive reflective , centrally perforated plane disc non-conductive reflective fixed thereon plane cylinder non-conductive non-reflective within which fixed spiral cylinder lesser internal angle non- conductive reflective along length in the recesses formed being fixed spiral conductive circuit in parallel at resistance , centrally perforated plane disc non-conductive non-reflective fixed thereon plane cylinder non-conductive non-reflective within which fixed spiral cylinder lesser internal angle non- conductive reflective along length in the recesses formed being fixed spiral conductive circuit in parallel at resistance within this fixed plane cylinder non-conductive reflective at separation , centrally perforated plane disc non-conductive non-reflective fixed thereon plane cylinder non-conductive reflective without which fixed spiral cylinder lesser external angle non- conductive reflective along length in the recesses formed being fixed spiral conductive circuit at resistance being within at separation plane cylinder non-conductive reflective , centrally perforated plane disc non-conductive non-reflective fixed thereon cone lesser internal angle non-conductive 14 reflective without which fixed short sections of plane cylinder non- conductive reflective at intervals along length in the recesses formed being fixed multiple circular conductive circuit in parallel at resistance being within at separation plane cylinder non-conductive reflective , centrally perforated plane disc non-conductive non-reflective fixed thereon cone lesser internal angle non-conductive reflective without which fixed spiral cone perpendicular vanes non-conductive reflective along length in the recesses formed being fixed spiral conductive circuit at resistance being within at separation plane cylinder non-conductive reflective , centrally perforated plane disc non-conductive reflective fixed thereon cone lesser external angle non-conductive non-reflective within which fixed short sections of cone lesser internal angle non-conductive reflective at intervals along length in the recesses formed being fixed multiple circular conductive circuit in parallel at resistance , centrally perforated plane disc non-conductive non-reflective fixed thereon cone lesser external angle non- conductive non-reflective within which fixed short sections of cone lesser internal angle non-conductive reflective at intervals along length in the recesses formed being fixed multiple circular conductive circuit in parallel at resistance within this fixed plane cylinder non-conductive reflective at separation, centrally perforated plane disc non-conductive non-reflective fixed thereon cone lesser internal angle non-conductive reflective without which fixed short sections of plane cylinder non-conductive reflective at intervals along length in the recesses formed being fixed multiple circular conductive circuit in parallel at resistance being within at separation plane cylinder non-conductive reflective , centrally perforated plane disc non-conductive reflective fixed thereon cone lesser external angle non- conductive non-reflective within which fixed spiral lesser internal angle cone angular vanes non-conductive reflective along length in the recesses formed being fixed spiral conductive circuit at resistance , centrally 15 perforated plane disc non-conductive non-reflective fixed thereon cone lesser external angle non-conductive non-reflective within which fixed spiral lesser internal angle cone angular vanes non-conductive reflective along length in the recesses formed being fixed spiral conductive circuit at resistance within this fixed plane cylinder non-conductive reflective , centrally perforated plane disc non-conductive non-reflective fixed thereon cone lesser internal angle non-conductive reflective without which fixed spiral lesser angle cone perpendicular vanes non-conductive reflective along length in the recesses formed being fixed spiral conductive circuit at resistance being within at separation plane cylinder non-conductive reflective , centrally perforated plane disc non-conductive non-reflective fixed whereon centrally perforated plane reflective surface, centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated concave reflective surface where on gradient is constant across its surface , centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated concave reflective surface where on gradient has two constituents each over a fraction of its radius , centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated concave reflective surface where on gradient falls evenly towards its centre , centrally perforated plane disc non- conductive non-reflective fixed on which centrally perforated concave reflective surface where on gradient falls decreasingly towards its centre , centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated concave reflective surface where on gradient falls increasingly towards its centre , centrally perforated plane disc non- conductive non-reflective fixed on which centrally perforated concave reflective surface where on gradient rises evenly towards its centre , centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated concave reflective surface where on gradient 16 rises increasingly towards its centre, centrally perforated plane disc non- conductive non-reflective fixed on which centrally perforated concave reflective surface where on gradient rises decreasingly towards its centre, centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated convex reflective surface where on gradient is constant across its surface , centrally perforated plane disc non- conductive non-reflective fixed on which centrally perforated convex reflective surface where on gradient has two constituents each over a fraction of its radius , centrally perforated plane disc non-conductive non- reflective fixed on which centrally perforated convex reflective surface where on gradient falls evenly towards its centre , centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated convex reflective surface where on gradient falls decreasingly towards its centre , centrally perforated plane disc non-conductive non- reflective fixed on which centrally perforated convex reflective surface where on gradient falls increasingly towards its centre , centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated convex reflective surface where on gradient rises evenly towards its centre , centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated convex reflective surface where on gradient rises increasingly towards its centre , centrally perforated plane disc non-conductive non-reflective fixed on which centrally perforated convex reflective surface where on gradient rises decreasingly towards its centre, centrally perforated (radius z) plane (from radius (x) to (x-E)) constant gradient (gradient equals (s/x) (from radius (x- E- to (z)) reflective disc) radius x) (where E equals length of disc edge), plane disc non-conductive non-reflective where on two lengths of encased non-emitting cable forming circuit with solid cylinder plane surface conductor at centre of disc , plane disc non-conductive non-reflective 17 where on two lengths of encased non-emitting cable forming circuit with solid cylinder concave surface conductor at centre of disc , plane disc non- conductive non-reflective where on two lengths of encased non-emitting cable forming circuit with solid cylinder convex surface conductor at centre of disc, means of securely combining stages, means of aligning a series of stages at some angle, centrally perforated plane disc reflective fixed thereon divergent arrangement , centrally perforated plane disc reflective fixed thereon convergent arrangement , centrally perforated plane disc non-conductive reflective fixed thereon elliptical conductive circuit at resistance within this baffle of elliptical non-conductive reflective cylinder external angular internal perpendicular sum <180s non-conductive reflective perforation not central to each , centrally perforated plane disc non-conductive reflective fixed thereon multiple elliptical conductive circuit in parallel at resistance within these baffle vanes of elliptical cylinder internal and external angular sum <180s perforation not central to all , centrally perforated plane disc non- conductive non -reflective fixed thereon elliptical conductive circuit at resistance within this baffle of elliptical non-conductive reflective elliptical cylinder external angular internal perpendicular sum <1802 non- conductive reflective perforation not central to each , centrally perforated plane disc non-conductive non -reflective fixed thereon multiple elliptical conductive circuit in parallel at resistance within these baffle vanes of elliptical cylinder internal and external angular sum <180s perforation not central to all.
2. A radiation transmission system as claimed in Claim 1 wherein means of securely combining stages includes fixing rod with grooves cut perpendicularly at separation non-conductive non-reflective. 18
3. A radiation transmission system as claimed in Claim 1 or Claim 2 wherein means of aligning a series of stages at some angle includes strut with rectangular base supporting two pairs of perpendicular rigid poles between which fixed at intervals cylindrical tubing parallel to base.
4. A radiation transmission system as claimed in Claim 1 or Claim 2 or Claim 3 wherein centrally perforated plane disc non-conductive non- reflective fixed on which centrally perforated concave reflective surface where on gradient falls evenly towards its centre includes a sphere with radius equal to (s) where s equals separation of components concave reflective surface.
5. A radiation transmission system as claimed in Claim 1 or Claim 2 or Claim 3 or Claim 4 wherein centrally perforated plane disc non- conductive non-reflective fixed on which centrally perforated concave reflective surface where on gradient falls decreasingly towards its centre includes concave reflective surface where on gradient at distance r' from edge of surface radius r equals 1 / (tan (1802 - (902 - (tan (-1) (r'/s)) 12 ) - (tan (-1) ((r-r') / (s-r'))) 12) ).
6. A radiation transmission system as claimed in any preceding claim wherein components would be joined by some means of coupling components.
7. A radiation transmission system substantially as described herein with reference to Figures 1-6 of the accompanying drawing.
PCT/GB1999/000662 1998-03-06 1999-03-05 Radiation transmission system WO1999045751A1 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
AU32659/99A AU3265999A (en) 1998-03-06 1999-03-05 Radiation transmission system

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Application Number Priority Date Filing Date Title
GBGB9804637.8A GB9804637D0 (en) 1998-03-06 1998-03-06 Radiation transmission system
GB9804637.8 1998-03-06

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US5121129A (en) * 1990-03-14 1992-06-09 Space Systems/Loral, Inc. EHF omnidirectional antenna
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FR2467526A1 (en) * 1979-10-12 1981-04-17 Varian Associates STATIONARY WAVE LINEAR ACCELERATOR WITH VARIABLE ENERGY
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US8711261B2 (en) 2003-12-05 2014-04-29 Sony Corporation Method of controlling semiconductor device, signal processing method, semiconductor device, and electronic apparatus
US9088741B2 (en) 2003-12-05 2015-07-21 Sony Corporation Method of controlling semiconductor device, signal processing method, semiconductor device, and electronic apparatus

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AU3265999A (en) 1999-09-20

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