DE10126510A1 - Radiative energy converter e.g. for conversion into electrical signals, uses continually generated matrix of filters - Google Patents

Abstract

A radiation transmission conversion machine transmits radiation through a variable and continually generated matrix of filters, specifically color filters, and which specifically circulates in a continuous process and which can be set with color filters and reset. The radiation passes through an optical waveguide in which radiation enters through the matrix into one end of the optical waveguide. An Independent claim is given for (A) a transport device (B) a computer (C) a store (D) a programming language (E) a signal input plane (F) a signal output plane, and (G) a signal code.

Description

State of the art

• - are transmissions of radiation signals via optical fibers with the final one Conversion to electrical signals. Only then are the electrical signals linked according to program.
• - are computer systems, the bit sequences in the signal form of a voltage difference (high- process low level)
• - are computers that work with three bus systems (control, address, data bus)
• - is the differentiation between control systems (PLC) and general data processing.

Advantages of the invention

• - computers with higher performance
• - Computer for controls and general data processing. This results in high permeability for E-Business / CAD and CAM processes
• - Three-dimensional image transfers

General description of the invention

Due to the wave range of radiation (IR / light / UV) that can be transmitted via optical fibers, different energy levels are transported at the same time. The energy of a wave range also contains information about itself:
The statement at which level the wave range is energetically.

The information (E) is defined via the frequency (f) of the respective radiation area and the Plank quantum of action h.

E = f.h.

Two pieces of information can be obtained from radiation:

• - Basic information bit pattern
  Radiation available - yes / no?
  Corresponds to high / low levels of electrical signals
• - Additional information processing level
  Radiation at what energy level (E) available?
  Corresponds to different voltage levels of electrical engineering systems

The basic principle of the calculator is based

• - firstly on a logical (Boolean) AND link of the incoming Information (radiation) with stored information (matrix pattern).
• - secondly, to evaluate the energy content of the radiation as additional information.
• - third use of the additional information by assigning the basic information to parallel processor levels of the computer.
• - fourth, merging the processed by the various processors, Basic information on an overall result.

Description of the INPU - INput Processor Unit ( Fig. 1)

The INPU consists of the parts
Drive motor ( 1 ), drive roller ( 2 ), set laser ( 3 ), radiation transmitter ( 4 ), reset laser ( 5 ), matrix tape ( 6 ), paint mixer ( 7 ), filter paint container ( 8 ), masking paint container ( 9 ), paint dryer ( 10 ), upper deflection roller ( 11 ), lower deflection roller ( 12 ), and radiation receiver ( 13 ).

In order to increase the number of possible combination combinations, there are more Push the matrix tapes in front of the basic matrix tape.

The following additional parts are required on the processing level:
2.-n. Matrix belt ( 14 ), upper deflection roller ( 16 ), upper pressure roller ( 17 ), lower pressure roller ( 18 ), lower deflection roller ( 19 )

Other required parts per matrix band are parts 1 to 3 and 5 to 12, as well as the baffle plate set laser ( 15 ) and baffle plate reset laser ( 20 ).

The drive motor ( 1 ) drives the matrix belt ( 6 ) via the drive roller ( 2 ). At the color mixer station ( 7 ), the holes of the matrix band ( 6 ) are filled with different transparent filter colors ( 8 ) according to the program. These filter colors filter the wave ranges blue, green, red, green / blue, red / green and red / blue from multi-channel white light.

Further filter color mixtures mask with a variable single-channel signal sequence from infrared radiation; red, orange, yellow, green and blue light and ultraviolet Radiation the signal to be processed.

The station with black masking paint ( 9 ) can fill individual or all holes of the matrix tape according to the program.

The paint dryer ( 10 ) dries the filter colors ( 8 ) and the masking paint ( 9 ).

The matrix band ( 6 ) runs over the upper deflection roller ( 11 ) into a vertical position and past a setting laser ( 3 ) which, in accordance with the program, shoots out the light passages once the matrix band ( 6 ) has been fully masked. A baffle plate ( 15 ) prevents unintentional patterns from being produced on a further matrix band ( 14 ).

The radiation transmitter ( 4 ) can be a cathode ray tube, an LED combination, the end of optical fibers or a combination of all of the above elements.

The emitted radiation passes through the matrix band ( 6 ) and strikes the radiation receiver ( 13 ) which converts the radiation into an electrical signal. The electrical signal is represented equivalent to the emitted light quanta as a voltage swing of different heights and interval lengths.

For example, a single optical fiber end is described as a radiation transmitter ( 4 ):
The following transmitted signal combinations are possible:
As a single signal
White light: yes / no
As a single signal
Infrared or red or orange or yellow or green or blue or ultraviolet yes / no
As a multiple signal sequence
Infrared and / or red and / or orange and / or yellow and / or green and / or blue and / or
Ultraviolet yes / no

These signal combinations hit the matrix band ( 6 ) and are processed in accordance with the conditioning of the radiation transmission holes.

The following logical linking options result with a matrix band:

E1 ^ = radiation:
present ^ = 1
not available ^ = 0
E2 ^ = radiation passage matrix band:
open (free or filter) ^ = 1
closed (100% black) ^ = 0
E3 ^ = radiation:
always available
E4 ^ = radiation passage matrix band:
alternately open / closed
A ^ = radiation:
present ^ = 1
Intensity ^ = level
not available ^ = 0
C ^ = radiation:
clocked (e.g. depending on E4)
for control

Assignment of the processor level depending on the energy level of the radiation:
Infrared radiation: level 1-49
Buffers: level 50
Colored light: level 51-59
Buffers: level 60
White light: level 61-69
Buffers: level 70
Ultraviolet radiation: level 71-99

Description of the computer block diagram ( Fig. 2)

The calculator consists of the parts
1 TRAPU: Translation Processor Unit
2 INPU: Input Processor Unit
3 PAPU: Parallel Processor Unit
3.1 PURAM: Processor unit with RAM memory
4 COLPU: Collector Processor Unit
5 OUPU: Output Processor Unit
6 CONPU: Controll Processor Unit
6.1 BIOS: Binary input output system
6.2 ROM: Read Only Memory
7 CEME: Central Memory
7.1 LIB: Library
7.2 RAM: RAM memory
7.3 SAFE: safety memory

The computer's bus system consists of
Data bus for data flowing through the computer from the input interface via TRAPU ( 1 ) to the OUPU ( 5 ) or stored in the CEME ( 7 ).
Library bus for the transport of programming languages, natural languages and other character sets, which CEME ( 7 ) makes available to the other processor units as internal computer syntax.
Control bus for general control tasks
Clock bus for clock synchronization between the processor units. The clock bus is decoupled from the control bus as an independent function.
Address bus for general address assignment of the data
Matrix bus for address assignments of the matrix fillings in the INPU ( 2 ) and OUPU ( 5 )
P2P_Bus as Picture to Picture Bus for direct picture transmission.

Data types are
A Analog: Analog measurement and control signals
B bytes: standard data
D Digital: digital measuring and control signals
V Voice: sound waves, primarily speech and music
R Radiation: radiation, mainly infrared, light and ultraviolet

The TRAPU ( 1 ) converts the incoming data types A, B, D, V into the R data type, taking the internal syntax into account.

The INPU ( 2 ) evaluates the data type R of the TRAPU ( 1 ) and data type R received from external transmitters (detailed description Fig. 1)

For incoming images that are to be output immediately, the INPU serves as Signal amplifier. Data type R with identifier "P" becomes data type B directly to the OUPU Posted.

The PAPU ( 3 ) consists of several PURAM processor units (3.1., 3.2.,... 3.99.), Each with its own RAM memory.

The type B data selected by INPU ( 2 ) are processed in parallel by standard processors.

The COLPU ( 4 ) merges several individual data records of type B, which are received from the PAPU ( 3 ), into a data record of type B.

The OUPU ( 5 ) receives the collective data record B from the COLPU ( 4 ) and converts this into data types A, B, D, V and R, taking into account the internal computer syntax. Depending on requirements, data records of type B are sent to CEME ( 7 ) ,

Data type B, which is received by the INPU via the P2P_Bus, is used directly as data type R sent out.

The CONPU ( 6 ) is responsible for the control of all operational and data flow functions of the computer. The operating system of the computer is contained in the CONPU ( 6 ) with BIOS ( 6.1 ) and ROM ( 6.2 ).

CEME ( 7 ) is the central memory of the computer. Are sub-memories
LIB ( 7.1 ) as the library for programming languages, natural languages and character sets
RAM ( 7.2 ) as working memory
SAFE ( 7.3 ) as backup storage

Description of the projection system ( Fig. 3) The components of the projection system

1

Crane track rail

2

Katz running rail

1

3

Katz running rail

2

4

Gantry

5

crane impeller

6

Head support cylinder

7

trolley

1

8th

hoist

1

9

trolley

2

10

hoist

2

11

Optical fiber bed

1

12

louvre optics

1

13

Fiber optic bundle

1

14

radiation receiver

1

15

White light transmitter

1

16

Optical fiber bed

2

17

louvre optics

2

18

Fiber optic bundle

2

19

radiation receiver

2

20

White light transmitter

2

21

Filter colors translator

1

22

capstan

1

23

matrix band

1

24

Reset laser

1

25

idler pulley

26

casing

1

27

bus line

1

28

Filter colors translator

2

29

capstan

2

30

matrix band

2

31

Reset laser

2

32

idler pulley

33

casing

2

34

bus line

2

35

lifting cylinder

1

36

cross suspension

1

37

lifting cylinder

2

38

cross suspension

2

39

longitudinal chassis

40

along bike

41

Longitudinal running rail

42

Cross running rail

1

43

Cross running rail

2

Basic principle of the projection system

Commercial graphics programs produce three-dimensional effects in printing and Screen output, among other things, by offset layering of object layers with corresponding color gradients.

The projection system for generating three-dimensional moving images works with several projection levels. These are free to each other within the display space flexible and freely combinable with each other in terms of the color grid.

As is common with drawing or graphics programs with "layers" or layers at the same time due to the transparency of the projection levels through the level in the foreground can be seen up to the background level.

The intensity of the emitted light is from the foreground to the background level increasingly.

Functional description of the projection system

Preliminary remark: A sub-system is described; the same applies to the tandem system same.

A transmitter unit for radiation is mounted in the housing ( 26 ) and is constructed analogously to the described FIG. 1. A matrix belt ( 23 ) is set in motion by a drive shaft ( 22 ). The matrix belt ( 23 ) moves in an endless loop over deflection rollers ( 25 ). The filter color setter ( 21 ) is controlled via the bus line ( 27 ). In accordance with the program, filter colors are introduced into the radiation passage openings of the matrix band ( 23 ). The color pattern migrates to a white light source ( 15 ). The white light passes through the colored radiation passage openings of the matrix band ( 23 ) into the respectively directly opposite ends of the optical waveguide of the radiation receiver ( 14 ). The individual optical fibers are brought together in an optical fiber bundle ( 13 ) and laid again as individual wires in the optical fiber bed. The individual optical waveguides end in a raster optic ( 12 ). A lens system is assigned to each optical fiber end. The light that is fed into the radiation receiver ( 14 ) emerges again as an image point at these lenses.

The means of transport for the optical fiber bed ( 11 & 16 ) and the grid optics ( 12 & 17 ) is similar to a 2-girder overhead crane.

The crane undercarriage ( 4 ) drives the crane wheel ( 5 ) over the crane running rail ( 1 ). Two crane trolleys are connected to each other via two movably suspended, telescopic trolley tracks ( 2 & 3 ).

The trolley tracks are in the basic position at an angle of 90 ° to the crane track arranged.

A total of 4 crane wheels are available. A head carrier cylinder ( 6 ) is located between each two crane wheels ( 5 ). With this head support cylinder ( 6 ) the wheelbase of the crane wheels ( 5 ) can be changed to each other. This results in a position of the trolley tracks ( 2 & 3 ) in relation to the crane running track ( 1 ) that deviates from the basic position.

The hoist ( 8 ) is attached to the trolley ( 7 ), which moves along the trolley track ( 2 ). The optical waveguide bed ( 11 ) and the grid optics ( 12 ) are suspended from the lifting mechanism ( 8 ).

The optical fiber bed ( 11 ) and the grid optics ( 12 ) can be positioned in the planes of the display space using a crane trolley ( 4 ), adjusting cylinder ( 6 ), trolley trolley ( 7 ) and lifting gear ( 8 ).

The longitudinal running rail ( 41 ) is located vertically under the crane running rail ( 1 ). The housing ( 26 ) can be tracked in synchronism with the movements of the optical waveguide bed ( 11 ) via the longitudinal carriage ( 39 ), transverse carriage ( 36 ) and lifting cylinder ( 35 ). As a result, the optical fiber bundle ( 13 ) is always held in an optimal position.

Description of the raster optics system ( Fig. 4)

FIG. 4 shows several raster optics and means of transport as described as a system module in FIG. 3.

The arrows show the movement possibilities of the image projecting raster optics in the display space

Description signal code

The alphabet contains the systematics 1 + 3/1 + 3/1 + 5/1 + 5/1 + 5.

Vowels A and E are followed by 3 consonants.

The vowels I, O, U are followed by five consonants.

There are five groups that can be coded with five technically producible light-emitting diode colors (LED) and infrared light-emitting diodes (IRED):
A ^ = red / E ^ = orange / I ^ = yellow / O ^ = green / U ^ = blue

The consonants following in the group are made up of the basic color and an additional one Infrared radiation IR1 / IR2 / IR3 / IR4 / IR5 is formed.

Claims (20)

1. Machine, characterized in that radiation is transmitted through a variable and continuously generated matrix of filters. 2. Matrix according to claim (1), characterized in that this in a continuous Process runs and can be set and reset with color filters. 3. Optical waveguide, characterized in that it contains radiation through the matrix Claim (2) enters one end of the optical fiber. 4. Optical fiber grid, characterized in that several optical fibers according to Claim (3) are arranged in a transparent disc. 5. Transparent pane according to claim (4), characterized in that this in one spatial coordinate system is freely positionable. 6. Means of transport, characterized in that there is one or more transparent Move disc (s) according to claim (5) in one or more levels of a room can. 7. Means of transport, characterized in that there is one or more machine (s) after Claim (1) can move in one or more levels of a room. 8. Means of transport according to claim (7), characterized in that it is the means of transport according to claim (6) with its movements in space follows in whole or in part. 9. System of machines according to claim (1), optical fibers according to claim (3), transparent panes according to claim (4), transport means according to claim (6) and Means of transport according to claim (7), characterized in that the transparent Disks positioned within the driving range of the means of transport in the room and the Optical fibers are supplied with radiation by a process according to claim (3). 10. Optical waveguide according to claim (3), characterized in that the Radiation exit end is designed as a lens. 11. Computer, characterized in that a logical link between Radiation quanta and a masking matrix takes place. 12. Computer, characterized in that depending on the radiation frequency Logic logic signals according to claim (11) at different levels processed in parallel. 13. Computer, characterized in that in a masking matrix according to claim (11) Filters are introduced that break down white light into its spectral colors. 14. Computer, characterized in that at least one further masking matrix it is ordered that the logical linking options expand from this. 15. Computer, characterized in that it contains more than three internal bus systems. 16. Memory, characterized in that character sets and programs for it Conversion of signals from electrical energy into signals from radiation energy are deposited. 17. Programming language, characterized in that this is the dual information of a Radiation as information "signal pattern" (equivalent to a bit sequence) and at the same time as  Information "energetic state" (equivalent to different voltage levels) used and with other physically or chemically generated or already existing Signal patterns logically linked. 18. Signal input level, characterized in that any incoming Programming language into a computer-internal programming language according to claim (17) is converted. 19. Signal output level, characterized in that an internal computer Programming language according to claim (17) in another programming language is converted. 20. Signal code, characterized in that it has the different energy levels of Radiations used as an information pattern.