GB2303015A - Digital video image-response predictor filter system - Google Patents

Abstract

The response predictor system method details the neural vision signal processing method to differentially interconnect the derived interframe quartic vector signals, as binary Boolean variables for computational processes executed by a serial hopfield network congery of quartic properties and functions in the intermediate Median and Majority filters, image icon selection and control points, and the datarate reduction to a parallel 2-bit form of machine vision change states, as occuring between fully digitised video frames. The psychovisual dynamic icon display is for up to six defined functions, and the measurement and control interface for thirteen flags. The digital video icon filter has a pseudocolour segment monitor screen for the vision motion viewer.

Description

Description.

DIGITAL VIDEO IMAGE-RESPONSE PREDICTOR FIL TER SYSTEM VINCAD - dynamic visual icon and control filter.

Claims.

The neural vision channel architecture of invention for digital television, in specific computational description is of a video image impulse response filter system, for viewing dynamical picture change on screen image motion multi-code displays. There are optional video frame data interfaces for binary quantitative, kinematic frame reconstruction, measurements, and control change states for instrumentation, machine-vision event occurrences within a quartic pixel image, and pictorial psychovisual icon display.

The particular implementation is the digital video television system utilisation of motion canon classes for singleton attribute or motion canon, the quaternary Kenn variable Kq with [bI1to4, 'aut',vel'] taxonomy, and further interframe changes for quartic logic property tbIltol3] vector flags.

The video computer differential (# T) system, on interframe threshold binaries for pixel flag distribution, translation, and delivery processes, provide motion or attribute change states in binary logic (b) flag '0'/'1' detection. The initial motion univector (M/m) occurrences can undergo spatial and temporal quaternary noise, interference and intrusion b(n) elimination by canon class 6 filtration (Kq) for vector b(n) flags.The noise reduction implements either motion canon class 1 or (+) canon class 2 for the 'One-Bit' unified 'b(1)+b(2) = > b(n) resultant vector flags, from prior specific description within "Bandwidth Or Datarate Reduction", "Multiple Visual Display From Motion Classificatiorls", "Mean Impulse Response Filter", "Majority Vector Encoder", and/or the "Improved Majority Filter" in the overall specification.

The spacio-temporal encoding of motion canon class 6, as the sum product vector of the spacio-temporal b(n) flag, feeds into the second interframe temporal-domain memory (6t3) transfer of the 'doublet', for the Boolean language 'nND' 4-way divisional ring relationship to provide a selection of four distinct binary singleton [bI1to4] flag output pulses of the 1st order.The precise language syntax profile of the entire 'NND' then 'OR' gate relationship logic combinations are for the vector binary '0'/'1' transitions between unique 2nd order vector ('aut' as b(7),'vel' as b(13) flags, and later (t Pkn+1) frame 3rd order vector (bI5tol2) flags on machine states following, (Pkn,x,y) = > (M/m.St) = > FbIito4J = > '1'= > b(m), at Pkn+i, with b(m) = > [bI1to4] = > (bI5to13 = > '1' = > b(m), by later transition and further frames using quantum pair vectoring.

The output interpolation 'pseudocolour' of a 'colouring' icon display screen is vector analytic from Boolean quaternary quantum ('p3#', 'q3#') pairs, with interface (I/F) output inter-connection for frame vector flag (b) video metrics (1to13) in instrumentation for measurement and control systems.

The distant communications and control line signalling is quantitatively defined ('p3#','q3#') for the further Boolean Galois Field GF(2) at destination. The third virtual synchronous finite impulse response (FIR) separation is by the interframe transversal (#ta) codification in a parallel 2-bit translation transmission and delivery on a tertiary section derivation of the temporal quantum (p3#,q3#) pairs. These are through three 'active' temporal Boolean LbIlto3] channel equations, for all the image change states of the four canon class quaternaries set from pixel image change criteria, in division from positive binary inlets to the Boolean divisional quantum vector or quaternary tbIlto4] ring flag(s).The structural analytic section of the 'finite temporal-domain impulse response filter' (FT-DIR-filter) has variant extensions. The further development is a parallel translation 2-bit form of the distributive system filter, in reconstruction to 'colour', 'highlight' or 'darken'/ 'blacken' the scene pictorial image by an interpolation with visible 'colouring' from the luminance (B & or monochrome) source picture content.

The binary logic calculus closes, on a convergence tri-fringence (1-3) matching the flag channel selection and control system into the parallel double-twin logic of two 2-input open OR-gates, for the parallel 2-bit translation quantum ('p3#','q3#') pair delivery.

There are two object orientations (m = 2 and m = 3) in the program language profile and triple class (1-3) syntax, for the image impulse group of a full (m = 1) and dual differential (m = 2/3) delivery quantum, as the Boolean interframe intrafield quantum ('p3#','q3#') pair.

The neural translation vector channel is for the Galois Field GF(2), and relieves the need at any destination for a 'real' FIR serial one-bit' memory transversal (#t3) 'doublet' of a further temporal-domain delay. The finite Galois Field ('p3#', 'q3#') GF(2) in the double-twin 2-bit quaternary is for binary logic signal transfer to any (distant) destination sub-system.

Addltionally the exclusive motion canon class 2 for the 'retroversal' vector, or similarly class 3 for the 'reversal' vector are initially in bi-jection separation for the partial (m = 2/3) latin 'aut' function of the flag (b) = 2/3 multiplex, with an overall truth Exclusive-OR change on the (p,q or 'p3#', 't3#') property function [('p' q') = > '1' = > TRUE = > b(7) = > 'aut'].The intermediatary tri-state image changes are the triple logic property of vel' at zero (b(1)+b(4)] = > 'O', with 'aut' at one ib(2)+b(3)] = > '1', and vice versa as the complementary tri-state image change in the triple logic property of 'vel' at zero tb(l)+b(4)] = > '0', while 'aut' at one b(2)4b(3)j = > The The parallel 2-bit vectors translate in the neural spine network of the video interconnection congery channel.

The quaternary channel logic equations are defined for multiple destination distribution of the advanced quantum system for vision data distribution by a one to one, one to many, or many to one signal multiplex, within a pathway graph distribution by divisional branch tree structures.

The invention architecture comprises of distribution logic elements for the transformation impulse image translation vectors of the temporal containment mapping functions. The parallel 2-input live Boolean relationships of the multiplex [b(1)+b(2)] OR-gate forward-data (p) property, in circuit parallel with the multiplex [b(1)+b(3)] OR-gate rearward-data (q) property, are in the double-twin 2-input open OR-gate quantum delivery of the 2-bit translation vectors. Each filtered quantum function is in code symmetry about the object image centre-line ( < /L) of the video frame functions, as first generative from the motion class IbIlto3/43 analyser (sty) lattice section of the preceding finite temporal-domain impulse response filter.Boolean logical equivalences for the spatio-temporal relationships, equations, and functions giving identical image response resultants are assumed inherent.

The advanced quantum channel system of invention in the specific description here is of one embodiement example only, as depicted in illustration by the following list of relevant drawings and diagrams for the datatarate reduction scheme.

Figure 1. The overview block diagram of the system scheme architecture, with intermediate Median and Majority filters feeding the 1-bit serial into the local FT-DIR-filter terminus and quantum OR-gate drivers, with the multi-pole neural parallel quantum of the translation vector 2-bit pair to destination.

Figure 2. The diagrammatic block basis of the intermediate Median ('qi') and serial Majority 'One-Bit' b(n) filter, for the selection and control FT-DIR-filter terminus and quantum OR-gate drivers for the neural network channel, with input majority and mean impulse response filters, for delivery vector [bI1to13] flags in the destination sub--system, and the video motion viewer system.

Figure 3. The double-twin OR-gate of the neural network channel translation filtering the quantum ('p3&num; ', 'q3&num;') pair of delivery vectors through the selection and control of the motion class analyser lattice, for three orders of canon (b) flag reconstruction, for colourising the video luma with chroma interpolation for the icon frame (Pk'n) reconsitution display, measurement and control class (b) flags, for the psychovisual motion display on a pseudocolour monitor.

Figure 4. The source distribution of quantum pair ('p3', 'qJ' ' to 'q3', 'pj') values for the translation vectors of the Galois Field (GF2), in the network (b) flag modelling b(m) for the canon class 1st order (bllto4], and inner 2nd order F'aut-2/3' b(7), 'vel-1/4' b(14), 'ps&num;', 'q3&num;' 1 and 3rd order [bI5to12] flags from fundamental discrete intrafield data, for distant branch distribution of vector (bIltol3] flag frames and/or psychovisual display.

Figure 5. The destination formula of the four class canon [bIlto43 representations, and the Boolean relation codification for the re-iterative intrafield quantum pairs ('p3&num;', 'q3&num;' = > 'q3&num;', 'p3&num;'), in translation vector contiguity for the parallel 2-bit neural channel network delivery to the distant Galois Field (GF2) first order sequence [bI1to4], for the divisional vector re-formation.

Figure 6. The the translation vector ('p3&num;', 'q3&num;') delivery geometry, mapping the quantum network property of the driver transfer function in the Galois Field (GF2) neural channel network, for image impulse response code of delivery vectors to the destination sub-system(s).

Figure ?. The Boolean 'AND' logic mapping for the translation lattice (bIlto4] fuctions in the double-twin routing from 2-input open OR-gate inter-connectedness, for the successive motion vectors b(m) of the quantum ('pS', 'q3&num;') pair.

Figure 8. Rn illustration of the neural channel processes for the Boolean canon network for flags [bI1to4] at destination, from the source intermediate filters through the finite temporal-domain impulse response filter, to 'aut-2/3' correlation of a vector flag b(2) or b(3), and 'vel-1/4' correlation of a vector flag b(l) or b(4) in the ;or-mux' image response multiplexer, and the 'onto' two 2-input open OR-gate drivers of the neural channel network.

Figure 9. An illustrative visualisation of the destination sub-system in the alternate annulytic ring 'aut-2/3' property with the halo gap 'vel-1/4' property function, derived from the finite temporal-domain impulse response filter (bIlto4J and double-twin OR gate function properties.

Figure 10. fln illustrative visualisation of the Venn Diagram schematic, after Boole, for each second order annulytic property 'aut-2/3' (SK,x) function, with the simultaneous halo property 'vel-1/4' (,e) function, both from within the defined logical universe (Pk'n, ot 3, x, y, [bI1to4]) of the 3-frame kinematic cascade diagram, after Hamilton.

Figure 11. The kleene algebra graph diagram of the Boolean neural network channelling for the image impulse responses in the binary translation vectors of the intrafield quantum ('qsfl','p,&num;') pair, through the FT-DIR-filter singleton 'or-mux' inter-connectedness, and class vector OR-gate drivers to the visual and control sub-systems of the destination sub-system.

Figure 12. The Truth Table for the video digital image impulse response filter system from the intermediate correlation filters, the selection and control FT-DIRfilter, and vector 'or-mux' visuals, through the double-twin 2-input OR-gate drivers for the neural channel network to translate the canonic delivery vectors of the quantum ('p3&num;', 'q3&num;') pair to any destination sub-system.

Figure 13. The Boolean division ring vector (1to4) first order, second order, and quantum pair vector correlations as graph flows for the quartic datarate reduction network between the FT-DIR-filter and motion class analyser lattice.

Figure 14. The FT-DIR-filter datarate reduction relationship pathways of the neural channel network for the congery quantum transcoding the video image response filter system.

Figure 15. By-pass and re-route of 'aut' + 'vel' vectors.

The digital video basis for visual quantum network (Figures 1 & 11) signalling, communication or transmission processes have parallel 2-bit focii in mode specification to the datarate reduction in the finite temporal-domain impulse response filter, in an extended quartic variation. The structural data methodology is for a standard design model on the recommendation ITU-R Rec. 601-4 BT system video standard for digital television. The secondary vector 'aut-2/3' or (+) 'vel-1/4' flags, in alternate by-pass multiplex, can re-route with binary colour interleave values for chroma (Y), and luma (Cb or Cr), for icon psychovisual display performance.

The vision frame process (Figure 15) for neural by-pass and re-route transcoding to psychovisual screen performance, relates to the BSI ISO MPEG-2 bi-directional 'B' frame, where b(n) video source forward-data ('1') or backward-data ('0') interpolate from the system adjacent 'I' frame Pkn+/-1 definition for NPEG-2, with the affine law derivation of motion class 6 in the receiver-set.

The co-ordinate pixelisation (Pkn,x,y,m), and the pixel point cardinality of the frame aspect proportion has a dimensionless picture length (16) by height (9) ratio (16:9) in picture definition of a video frame matrix. The prim intrafield matrix (# Pkn+/-1,#t1,x,y) definition is within a Church-Turing methodology for the computer memory program code, and logic sequence control for the geometrical algebra of kinematic attribute or motion vectors. A specific implementation can incorporate whatever data transfer medium, media or material technique for data communication, transmission, signalling, recording, or storeage for parallel (6t3) temporal 2-bit neural distribution (Figure 1).

The quaternary congery channel has a robust affine 1--bit serial rule vector b(n) flag feeding into the neural 2-bit parallel rule of the vision neural network congery, for the temporal quantum (eq3&num; ', 'p3&num; ' ) pair of translation vectors. Each has a 3-frame pixel-point origination function from (triad) spot brightness for the pixel-point waveform of geometrical delivery vectors (see Figure 13).

The video image motion correlator in methodological sequence definition has synchronous interframe relationships within the pixel-point data system for neural pixel flag (b) binary networking. fi strict algebraic syntax profile computes an adaptive numerical algorithmic technique in the definition of an advanced microelectronic (1P) video system. The piece-wise three-way vector channel tbIlto3] definition in the quaternary access splitter is for manual or automatic selection in algorithmic control, from the initial four-way neural (b) flag (1-4) generator, to later quaternary (Zi Pkn+/--1,St1,x,y,(bI1to13]) completeness.The code shows an intrinsic synthesis in the logical homogeneity of the inter-connectedness, and isotropic communication quantum transfer, within the incorporation of the principles of physics, for the vision image impulse response by selection and control programming, with the visual motion class display and alternative outputs.

The video intrafield binary logic of the quaternary division ring produces four singleton attribute or motion canon vector (b) flags tbIlto4], to include the two basic object motion initial orientations CbI2,33 by canon motion class 2 (rear) and 3 (front). Inputs are from camera stimulus, synthesis graphic, or visual simulus sources, for translation and interpolation processes on the triad pixel (Y,Cb,Cr or Y, U/V) cell group, for the video screen image of an icon pictorial display (Figures 2 & 10).

The image composite of basic scene of picture luminance, monochrome, or B & signal is derived from whatever source for luma with chroma composite interpolation for multiple clear 'colouring', or contrast 'highlighting' or 'blackening'/ 'darkening' stimulus. The binary chrominance (C) mix representions (Cr,Cb) are for kinematic motion or frame (^ Pkn) differential attribute changes, in the video luminance (Y, IR, thermal) signal. The digital 3-frame temporal (6t3) interval analyses are on image processes for artificial intelligence (41), machine-vision or robotics. The video (DIRFS) translation vectors are also quartic quantum ('p3&num;','q3&num;') pairs to enable the four-field fourfold m-descriptor to throughput a 'vel-1/4' or (+) 'aut-2/3' by-pass to chroma (C) interleave the re-route interlay.

The Median image perceptron filter.

(Figure 1 item 1) The frame interval pixel amplitude sampling from > = 4 input digits is the visual perception abstract from the multi-bit interframe (Zi T) delay. The forward-frame (ii Pkn+l) interpixel feed is through the arithmetic logic unit (alu) of the differential (# T) engine for the subtraction univector binary detection sign of a high logic '1 = > positive transition, in reciprocation from a low logic 'O'r) negative.

The scan cycle binaries are from the absolute difference limit threshold-transfer for the binary 'A' frame vector transforms.

The ecological multi-digit absolute difference (PAD) values for each pixel are computational from the (5/6) most significant bits (msb) of the differential signal. Integral digits are of adaptive significance in the cut-set amplitude calibration by trial spatial comparison procedures in retrospect to the previous pixel-point memory samples, and the parametricised logic of the reduction set (4-) chance OR-gate function volumes. The interframe ( T) differential calibration of the discrete 'one-bit' serial binary train logic follows, (Pkn+1 (-) Pkn)10 = > PAD-value10 > = NDLT-transfer transform = > logic '1' high = > TRUE = > univector (n/m)1s =) Pi'.

The neural perceptron logic of the interframe memory is the arithmetic collimation for the coherent

fluxion separation of the prime intrafield binary quantum in in the recursive 'doublet' of one interframe period (tt mS) delay. The later inheritence quantum 'float' 'qi value is a polarity flux formation for the quantum pair from the video 3-frame cascade input (Figures 1, 2, 3, 4 & 13).

The first intrafield quantum ('qt') later forms the temporal-domain (#t1) tensor within the intermediate "Improved Majority Filter". The intermediatary first 'majority' section filter is the multiple (#Pa2/4) interpixel period of 2 or 4 memory cells, around the spatial interval section for initial optimal (bo) flag substitution within the 3/5-pixel n--run-length code trains. The logistical (n-1)input circuit 'AND' structure primes the missing core (bo) flag logic. This zero impulse pixel-point exact replacement ('zipper') or injection function is summarative from adjacent interpixel memory (#Pa2/4) junctures, either side, for the divisional omission ('0') pixel vector (bo) flag emission property at logic '0'/'1'.The bi-pedestal elective franchise is on the neighbourhood either side of the spatial (bo) flag ('O') omission. The serial cell (#Pa2/4) memory in augmentation throughputs a continuous serial logic sequence (Figure 1 & 2 item 2 & 11) as follows, [(b1) # (b2) # (b4) # (b5)] = > (bo) = > ('q'), for the corrective (bo) onward feed into the temporal 'doublet' ( & 2) memory (NxPa. ) delay for first order 'AND' canonic correlations.

For intrafield ('q3&num;') spatial (#Pa1/2/x) singularity, twin, or species noise from intrafield quantum-slice scatter, or speckle filtration is by auto-correlation of random trial events in the following interframe transversal (St1 ) period of the temporal-domain memory. The filter comprises the additional 2-stage serial intervector (m1) processes of the "Mean Impulse Response Filter" (Figures 2, 3 & 11), essentially within the temporal-domain (#t1) 'doublet' memory period.The twin species of the single interpixel (6Pas) memory variant has both the Boolean first stage auto-correlation (. / & / ), and the second stage interpixel memory cross-correlation (+/ V) processing (Figure 9 8 & 11), by the instantaneous axiomatic spatial law as follows the full intervector ('p1') resultant (mo), (bi t b2) = > m1 = > (bi M bo) = > mo = > 'O'/'l' = > (b) Within the FT-DIR-filter (#t1) ) memory delay for the singleton framework [bI1,2], the motion canon class 1 singletons (m = 1) feed the forward (6t2) delay of the temporal schaefer stroke (1) class (n = > 2) flag (b) store formation, from motion or attribute canon class 1 (n = 1) through the temporal (#t2) transpose to (n = 2), for the temporal transpose group (n, m). This is the singleton b(m) vel-correlation transpose conversion delay of m = 1, n = 1 fed-forward to n = 2, m = 2, within the second analytic bi-refringence of canon class 2 closure, by the 'retroversal' image vector geometry constaint of the quaternary taxonomy variables. This synchronises the return of class 2 flag control, by temporal (n = 2) revectors from the first interval memory (#t1) period delay, for the temporal transpose group (n,m). The transpose vector conversion from class 1 to motion class 2 revector geometry is for sum product vector b(n) bi-directional 'B' frames.The affine 2-input OR-gate cross-correlation (+/V) function trains the 'fredkin' impulse law protection under instantaneous rules.

The motion-compensated tag (Y) data channel system option through transport vectors by vel ' and 'aut ' applies (see Figure 2).

The substitute correlation class b(n) flag for the 'One-Bit' motion class 6 'fall-back' of quaternary variable taxonomy is the vector (Kq) flag analysis following, Quaternary logic (Kq) = > [b(1)x#t2.b(2) + b(1)] = > b(n) flag, or if motion-compensated the m-descriptor vector.

The following "Mean impulse response filter" option on output binary data signals, operates primarily across the interpixel (nx6Pa.) delay by the (n+l)input 'AND' gate ( & h) auto-correlations. Then secondarily through the (nxSPb.

delay across the (n+1)input 'OR' gate function, for cross-correlations (+/ V) resultant in auto-corrective memory flag (b) output compensation on the affine b(n) flag substitution system. The second improved majority out lot application of the mean impulse response filter occurs before the temporal-domain (#t3) 'doublet' memory input of the following motion classifier analysis (b) flag (1-4) generator. A brace of mean impulse response filters are also locatable for the delivery vectors at each distribution destination. The post canon class filter location of the logic window for a moan impulse response filter removes scatter values from the interframe correlation filter itself.

The critical situation is before the following frame temporal-domain (#t3) for canon class division, in particular to include canon class 3 singleton b(3) flags, the 'reversal' vector.

The quadratic 3-channel tri-refringence near source.

(Figures 2 item 3, 3 item 10 & 4) The primary finite temporal-domain impulse response filter for the Boolean canonic flag b(m) division of the quaternary [bI1to3/4] attribute rule of the first motion class (1-2-3/4) analyser has a 3-way (b11to33 data organisation dominating the source univector (M/m) calibration system (Figure 2 item 3).

The Boolean canon class law of the datarate reduction channel LmI1to4] equations for the conditional quaternary "Vision Notion Classification Rnd Display" method determine a partial process computation. The contiguous video sequence on three consecutive pixel co-ordination frames is by the input 'finite temporal-domain impulse response filter' (FT-DlR- filter) section, with the quaternary canon lattice of the attribute class (1-2-3/4) division of the finite impulse response (1-2-3/4) ring, for the singleton canon class [bI1to4] flags of the adaptive learning transform.There are linear interframe full LPkn-1 U Pkn+1] temporal union relationships in the hierarchical propositional calculus, with explicit circuit expressions for logical pointer connectives as equivalently non-vanishing to follow (see Figures 3 item 10, 4, 13 & 14), 1) For the 'fully motive' pixel change state conditions for image edge transitive conditions, feeding through the mutual auto-correlation 2-input 4ND-gate relationship. The binary physical law characteristic has equi-positive symmetry @# Pkn-1 U # Pkn+l] in temporal union, and a variable displacement

for the Boolean channel equation conditions.The property function is an indistinguishable pair of quantum samples in the second FIR transversal 'doublet' (#t2) delay for fixed-point vector definitions as follow, ('pJ' A 'q2') = > '1' = > TRUE = > b(1) flags, for canon class 1 display pixel 'green' regions in 'fully-motive' frame segmentations of the commutative double occlusion surface.

2/3) The intermediatary Boolean 'AND' dual and differential 'onto' classification is the special complement of classes 2 and 3, in their exclusive oblique bi-jection functions, via each of the two 2-input Boolean mirror reflective inversion AND-gate relationships. The canon class 2 and 3 properties have lateral symmetic logic rotation which is central about the intrafield memory mean delay interval of the interframe (#t3) temporal-domain memory. An input inversion rotation about the centre line of the 2-input AND-gate function is found between each of the differential motion classes 2 and 3.The physical multiplex OR-gate functions, and ' or-mux' properties characterisation, are within an inter-pixel species criterion of the network channel equations for the motion canon class laws, to discriminate temporal conditional progressions, positive as for class 2 [#Pkn-1 U #Pkn+1] and class 3 [# Pkn-1 U # Pkn+l1, from image attribute criteria to follow, (Z) the late or anticedent 'red' edge transition in a 'retroversal' vector attribute from adjacent video frames ('p3' ' 7 # 'q3') = > '1' = > TRUE = > b(2) flags, for canon class 2 trailing 'uncovering' or lagging edge display pixels in the 'red' frame segmentations, representing a Bayesian model of the 'Kanizsa triangle' occlusion surface.

(3) ) the early or precedence 'blue' edge transition in a 'reversal' vector attribute from adjacent video frames (# 'p3' # 'q3') = > '1' = > TRUE = > b(3) flags, for canon class 3 leading-edge 'covering' display pixels in 'blue' frame segmentations, representing a Bayesian model of the prime oncoming-edge occlusion surface.

For the vector b(4) flag change state sets imply the non--evanescent degeneracy vector (b) = 4 of the restoration flag b(4) logic evaluation. The transpondent ramification is the motion canon class 4 existential [# Pkn-1 U #Pkn+1] for 'stationary' or idle image surface conditions. The virtual logic '0' level null, for zero vector delivery in the synchronous time-slot periods is for phantom b(4) flag data of the empty-set core group for the translation vector quantum pair of both ('p') = > '0', and (q) = > 'O' in simultaneity (see Figures 3 8 4).

Definition Equations for the quqantum ('p3&num;','q3&num;') pairs.

(Figures 3, 5. 6, 13 and 14) The geometric 'onto' three class mapping cardinality of the diffraction lattice tree is as for the four division ring of the source FT-DIR-filter. The integral projective limit in the selection and control of parallel 2-bit convergence maximally matches motion canon class 1 'entrant', class 2 'retroversal', and class 3 'reversal' vector time-slot (b) flags alone. These commutative transitions are in full union when fed 'into' the temporal (6t3) parallel 2-bit focii of the translation vectors in the data path congery mechanism.

The temporal (6t3) algebra for the displacement vector screen display code is for the complex parallel 2-bit neuron, as the Galois Field GF(2) of the quantum ('p,&num;', 'q3&num;') pair in the neural network channel.

The extrinsic codification vector 'onto' transfer is from the double-twin neural 2-input open OR-gate bi-convergence which is recursive into the destination diffraction lattice division tree. The Boolean (b) dispersion network of the secondary quaternary b(m) division ring is to uniquely 3!6q) decode to four addresses (1-4), in temporal interactive accordance on selection and control with flag (b) channel 'AND' conditional b(m) equations. The broad 'added' classes are the exclusive disjunction of 'aut-2/3' for the annulytic ring (re-pair), and the double commutation of 'vel-1/4' for the halo gap, both are of the 'or-mux' (+) chance multiplex, on double recursion from the four motion class canonic flag LbIIto4] singletons, here in the 3-way federal conformation.

The containment 2-bit frame and line scan period mapping properties are from interframe Fourier temporal (#t3) variables, from interval Laplacian filter mask transforms.

The re-formulation to the parallel data 2-bits (p3&num;,q3&num;) has a double-twin minimality of the 2-input open OR-gate functions, in the neural quantum spine drivers for the delivery property decomposition in the Galois Field GF(2) (see Figures 3, 5, 6, 12, 13, 14).

The maximum universal quaternary (APkn+/-z, ti ,x, y, (bllto 13) in logic utilisation has an intermediatary Median and Majority filter for correlation enhancement. From the (Kq) channel processing in the regressive flag code 'fall-back' normalisation the fractal growth separation for the quantum 2-bit neural multi-pole branch distribution is from a vector b(m) matrix environment, for the transmission channel transfer network as follows, I) The frontal frame direction OR-gate driver data for respectively the 'fully-motive' or 'entrant' motion criteria (1), and the foreward leading edge or 'covering' motion criteria (3), for singleton flags to juncture quantum neuron ((b(1)+b(3)] = > 'q3&num;;') vectors, for instantaneously either of motion or attribute canon class 1 or 3, in division from each respective 'nND' correlation. The quantum system definition for frame frontal reconstruction follows, [('p2' # 'q2') #('p2'## 'q2')] = > 'q3&num;' = > TRUE = > '1' or {('p2'.'q2') + ('p2'.'q2')} = > 'q3&num;' = > TRUE = > '1' The The back frame direction OR-gate driver data for respectively the 'fully-motive' or 'entrant' motion criteria (1), and the rearward trailing edge or 'uncovering' motion criteria (2) for singleton flags to juncture quantum neuron [b(1)+b(2)] = > 'p3&num;' vectors, from instantaneously either of motion or attribute canon classes l or 2, in division from each respective 'AND' correlation.The quantum system definition for frame rear reconstruction follows, [('p2'#'q2') # (# 'p2'#'q2')] = > 'p3&num;' = > TRUE = > '1'.

or {('p2'.'q2') + ('P2'. 'q')) = > 'p3&num;' = > TRUE = > '1' These double--twin Boolean integral summations (or integrations) remain in temporal separation after network translation are lattice recombinant upon trial quantum chance (+) functions on random data sequences.

The signal translation vectors for parallel digital transmission are the quaternary quantum (p3s,qss) pair for the primary four motion canon class tbIlto4] flags from the video image impulse responses. The parallel focii 2-bit neural communications may be for multi-pole quantum ('p3&num;','q3&num;') pairs, in multiplex distribution from the 3-frame data cascade input video (Figures l 8 2).

Hence a second one-many congery channel network can feed the multiple visual (1-4) colouring display at any destination local sub-system from motion trio (bIlto3] classifications sent with flag b(4) only as an anticipation (Figure 1, 2, 3, 11, 12, 14). Each quaternion singleton (b) flag is in distribution of the quantum ('p3&num;','q3&num;') pair function, to each lattice segmentation b(m) function in the motion class analyser (1-4) lattice.The simple quantum generalisation model has the selection and control of the respective motion class [bI1to13] flags by simultaneous quantum pair binaries along each scan line

s # (#!#q) = > ('q','p') = > ('p3&num;','q3&num;') = > '1' = > b(m) r (ti ) ( & t3) majority and mean impulse response filters at destination.

The further option of a matching balanced pair inlet of the discrete 2/4-input interpixel majority summarative injection filters, to replace missing singularity quantum ('p3&num;' or 'q3&num;') vector ('1') errors, along the video continuity of scan line quantum ('p3&num;' or 'q3&num;') vector segmentations which form the run-length code input to the "Mean Impulse Response Filter" pair.

The reflective symmetrical brace of cross matching "Mean Impulse Response Filters" are parallel quantum logic windows for self-correction. The signal protection has a circuit location to simultaneously reject or eliminate quantum (# Pkn+/-1,x,y) vector noise and/or (E-n) intrusion scatter, as occurs throughout the parallel neural network channel. Each quantum neuron is kept within the spatial n-tuple interpixel memory (#Pa1/2/n) delay(s) for the (n+l)input (n = 2) AND-gate auto-correlation ( & S ) rejection for monary dilation.The spatial 'AND' instigation (m1) intervector results into the auto-corrective n-tuple interpixel memory (#Pb1/2/n) delay for the (n+1)input (n = 2 min) OR-gate cross-correlation (+ ) compensation to enumerate the singles, twins, or species logic for restoration quantum (mo) vector (p3,q3) output. The binary interframe singularities, twins or species occurrences inspecific to (n+l)input AND-gate auto-correlation and to vector quantum pairs are thereby removed.

Re-fringence equations for the quantum pair ('p3&num;','p3&num;').

The branch destination supports tri-refringence singleton re-generation of the motion class (1-4) vector (b) flags, in the motion class analyser (bIlto4] lattice of the division ring, from vector quantum ('p3&num;','q3&num;') pairs as follow in equivalence, i) The channel equations for 'fully-motive' or 'entrant' intrafield full-wave quantum vel-correlations as, 'p3&num;' A 'qs&num;') = > 'l' = > TRUE = > b(l), or, [p3&num;'.'q3&num;'] = > 'l' = > TRUE = > b(1).

ii) The channel equations for 'uncovering' or 'rearward' trailing-edge intrafield half-wave quantum aut-correlations as, ( 'p3&num;' # # 'q3&num;') = > '1' = > TRUE = > b(2), or, ['p3&num;'.'q3&num;'] = > '1' = > TRUE = > b(2).

iii) The channel equations for 'covering' or 'forward' leading-edge intrafield half-wave quantum aut-correlation as, (# 'p3&num;' # 'q3&num;' ) = > '1' = > TRUE = > b(3), or, ['p3&num;'.'q3&num;'] = > '1' = > TRUE = > b(3), iv) The channel equations for 'stationary', 'idle' or 'null' intrafield pixel zero-wave quantum vel-correlations as, (# 'p3&num;' # # 'q3&num;') = > '1' = > TRUE = > b(4), or, # ('p3' + 'q3') = > '1' = > TRUE = > b(4), or, ['p3&num;'.'q3&num;'] = > '1' = > TRUE = > b(4).

v) The appendix 'or-mux' channel equations for the 'aut-2/3' exclusive OR, an overall Ex-OR function property on ('p3&num;','q3&num;') of canon classes 2 or 3, in interframe pixel annulitic ring (foreshadow | aftershadow) 'aut-2/3' flag b(7) correlations from transport vector visualisation as follow, (# 'p3&num;'# 'q3&num;') # ('p3&num;'## 'q3&num;') = > b(2/3) = > b(7).

'aut-2/3' or b(7) as, (b(2) # b(3)) = > '1' = > TRUE = > b(2/3) = > 'aut-2/3', or b(7) as, [b(2) + b(3)] = > '1' = > TRUE = > b(2/3) = > 'aut-2/3'.

or b(7) overall as, m = > ('p3&num;' # 'q3&num;') = > '1' = > TRUE = > 2/3 = > 'aut-2/3', or b(7) overall as, m = > ('p3&num; ' # 'q3&num;') = > '1 ' = > TRUE = > 2/3 = > 'aut-2/3'.

vi) The appendix 'or-mux' channel equations for the 'vel-1/4' halo gap exclusive of canon classes 1 or 4 in interframe quantum double-differential 'vel-1/4' halo gap b(13) flag correlations (AND OR NOR or Ex-AND/NOR). from the transport vectors visualisation as following, ('p3&num;'#'q3&num;') # (#'p3&num;'##'q3&num;') = > b(1/4) = > b(13).

'vel-1/4' or b(13) as, (b(1) V b(4)) = > '1' = > TRUE = > b(1/4) = > 'vel-1/4', or b(l3) as, [b(1) + b(4)] = > '1' = > TRUE = > b(1/4) = > 'vel-I/4', or b(13) overall as.

('p3&num;' # 'q3&num;') = > ('p3&num;' # 'q3&num;') = > TRUE = > b(1/4) = > b(13) (Figures 6, 7, 8, & 9) The display 'pseudocolour' icon pictorial results from the morphological construction algorithm for a screen image, with predicate 3-frame procedures for geometric recognition indications by segregation regions from the motion or attribute canon class and secondary laws (Figure 10 - 14).

These are under individual prior axiom statement postulates in the fundamental definition of their physical temporal characterisation from the Boolean 3-frame cascade change states which have reversible neural attribute identities.

The mutually exclusive canon class 2 of the 'retroversal' vector, or the canon class 3 of the 'reversal' vector are each a sole b(7) flag as a respective feed to the Boolean 2--input canon class 'aut' multiplex property. The 'aut' tri-state class ('0', canon class 2 with 'aut-2/3', canon class 3 with 'aut-2/3') annulytic ring re-pair function is an integrative gate architecture in the 'or-mux' appendix.

The alternate connective for the exclusive dual m = (2/3) combination for the b(7) flag is the Boolean--Bernoulli (+/ V) chance function for the 'aut-2/3' = > tb(2)+b(3)] = > b(7) product vector, inclusive from b = > 2 OR b = > 3 equivalence (Figures 10 - 14).

The mutually exclusive canon class 1 of the 'fully-motive' vector, and canon class 4 of the 'null' vector, each as a sole b(14) flag as a respective feed to one of the Boolean 2--input multiplex canon class OR-gate properties. The 'vel' tri-state class ('0', canon class 1 with 'vel-1/4', canon class 4 with 'vel-1/4') halo gap function of the integrative gate architecture are in the 'or-mux' appendix. The alternate connective for the exclusive dual m = (1/4) combination for the b(14) flag is the Boolean-Bernoulli (+) chance function for the 'vel-1/4' = > tb(1)+b(4)] = > b(14) product vector, inclusive from b = > 1 OR b = > 4 equivalence (Figures 5, 9, 10, 11 and 12).

The distinct change states for the canonic class 1 pixels in the 'green' region, or the canonic class 4 pixels in the 'magenta' region, are each a mutual reciprocal binary function. The other distinct change states for the canonic class 2 pixels in the 'red' region, or the canonic class 3 pixels in the 'blue' region, are each a mutual reciprocal binary function (Figures 10 - 14).

The 'aut-2/3' derivation of class 2/3 pixels are in the respective ('red' + 'blue'] region, with the 'vel-1/4' derivation of class 1/4 pixels in the respective green as 'magenta'] region (see Figures 10 & 14).

There are additional sub-system (b) flag metrics in the vector interface (I/F) to the "Digital Impulse Response Filter System", in a cyclic frame group for relative scan-line measurements, and complex dynamic tbIltol3] flags for frame and scan-line controls.

By an attribute priority gate (NOT/OR) daisy chain sub-system, further FT-DIR-filters network in on the canon class b(m) priority of the hierarchial logic hasse functions, join from each Boolean quaternary 4-way analysis of their vector b(m) divisional rings for the inferior number function resultant output of the lowest numbered class b(min) flag.

The re-writeable frame-store memory of flag tblltol33 pixel interpolation interleaves the luma/chroma cycle to the mosaic reconstitution (Y,Cr,Cb) icon pictorial of the demi-elliptic annulytic ring (re-pair) and halo gap functions, to correlate from input luminance (Y) and class colourisation chrominance (Cr,Cb) frame (Pk'n, (b)) components of the triad cells (Pk'n,Y,Cr,Cb). The Kenn Diagram Kq (see Figures 10/11 & 15) illustrates the screen icon interleave psychovisual display.

Thetintermediate quantum Median and the temporal Majority of the Boolean channel class 1.2 filter, for the FT-DIR-filter analyser congery provide a motion or attribute canon class (bI1to4 flag delivery scheme, to transmit interval vectors (M/m) for the television video of the pseudocolour segment viewer monitor, to give a psychovisual dynamic performance display. The partial homeomorphic method relationship of quartic vision systems make use of datarate reduction employing a classification channel.The temporal quantum Median (8/1 o into 6/s) separation rules and the channel Boolean equation laws for quartic translation vectors are for video filter vision viewers, transmission and communications, in parallel quantum pairs of Boolean quartic variables in the quaternary 'One-Bit' binary taxonomy. The screen psychovisual display performance of the indication re-route view from the pseudocolour segment monitor is illustrated by the quaternion Kenn Kq diagram (see Figures 10/11 & 15).

The motion-compensated interpolation (MCI) interleaves the chrominance (C) counts by-pass, on the alternate (Cr or Cb) re-route ( ) > multiplex to the icon image (Y,Cr,Cb) reconstitutional display frame ('photo'). The binary pixel-point counts of the quartic transport vectors, from the improved 'predictor' filter for digital video systems with a 'majority' vector encoder, use the forecast temporal transpose (m,n), in the (n = 1) feed forward for decorrelation inhibition vectoring to cross-correlate the motion class 6 (m = 1, n = 2 sync b(2)) in the ((b(l)+(n.b(2))] = > b'(n)) sum product, in the noise reduction 'One-Bit' filter 'fallback'. The independent (o) single-action stochastic, osculation pixel point singularities which may be chaotic 'trou noir' or 'black holes' to nature, are eliminated in the 'MIRF' emergent affine vector b'(6) flag. The second mean impulse response filter then feeds the finite temporal domain impulse response filter, for the b'(6) intelligent knowledge-based system of the umbilical Boolean division ring (bllto4] singletons for transport vectors.

Claims (8)

Claims.

1. A method of video vision distribution and display system by the neural network channel, in the quantum ('pa&num;', 'q3&num;' ) pair of parallel (2-bit) intrafield translation vectors, for the motion vector (b11to13] flag delivery to the local terminus and/or destination sub-system(s), with the motion display icon (Pk'n) visual on four canon classes for the two demi-elliptic halo gap and annulytic ring functions from class flags (b) for instrumentation, measurement and control, and/or digital video and television systems for a pseudocolour vision motion display.

2. n method of video visual image motion classification and display as claimed in claim 1, using parallel data transmission in alternate quantum ('pS', 'q&num;') pair formation, in the simultaneous translation of two intrafield logic binaries, from the serial quantum pair source filter to any motion class (1-4) analyser for the 'aut' or 'vel' chrominance (Cr or Cb) by-pass to re-route (Cr,Cb) hue colour values to the pseudocolour icon image in the re-construction frame for video interpolation with source luminance (monochrome, IR - thermal, B & ) signals for a pictorial icon image motion display of four canon classes, to produce the demi-elliptic annulytic ring b(7) and/or halo gap b(13) display functions.

3. A method of achieving a digital video image response predictor filter system as claimed in claims 1 or 2, wherein an intermediate (e/10 into @/@) quantum Median filter feeds a serial intrafield subsection 'majority' spatial congery, comprising of a substitutional 'zipper' injection (3x3 or 5x5) filter, and a Boolean channel class 1.2 vector b(6) filter, with both the temporal-domain (#t1) 'MIRF' number (2) logic-filter (3x3) and the output 'MIRF' number (2) logic-filter (3x3) for the 'One-Bit' vector b'(n) flag, to feed into the Boolean m-descriptor division (bI1to3 translation vector ring.

4. R method as claimed in claims 1 to 3, wherein a video digital image response filter system, with intermediate Median and Majority filters, for the 'One-Bit' sum product vector (b'(n)) in serial feed into the finite temporal-domain impulse response filter with two 2-input OR-gate drivers for the analytic translation vectors of the 'Two-Bit' quantum ('p3&num;'.'q3&num;') pair, for canon (b(m)) reconstruction chroma to interleave on by-pass the re-route interpolation frame (Pk'n) display, a digital vector flag (bI1tol3 filter system for measurement and control, or video vision motion viewer systems for 'vel' + 'aut' display.

5. n method of achieving a video digital image response filter system as claimed in claims 1 to 4, wherein the intermediate Median and Majority filters for the 'One-bit' motion class

6 serial vector b'(n) flag provide translation vectors by the quantum pair to the destination sub-system for the mirror brace of majority input and mean impulse response filters for delivery vectors, and motion class analyser lattice for video frame icon interpolation, and/or 'colouring' re-constitution display.

Claims 6. n method of achieving a video digital image response filter system, as claimed in claims 1 to 5, using a vector binary quantum pair by simultaneous temporal alternation, in a 3-frame data cascade from the interframe differential for video viewer display, transmission, communications, instrumentation or recording systems.

7. A method of achieving a video digital image response filter system as claimed with the text description and set of drawings for illustration.

8. fi device for a video digital image response filter system as text description with illustration by the set of drawings.