| CPC H04B 10/1149 (2013.01) [A61L 2/10 (2013.01); A61L 2202/11 (2013.01); A61L 2202/14 (2013.01); A61L 2202/25 (2013.01)] | 8 Claims |
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1. Radiation field-based hybrid object-supply system, consisting of an arrangement of both signal-generating and signal-capturing and signal-processing transmission and/or system components on the basis of the radiation coupling of UV-optical as well as UV-electrooptical and/or UV-magneto-optical of both active and passive transmission members, characterized in that
a UV (ultraviolet) photonic radiation field of a defined polarization signature and a defined geometric, temporal and amplitude signature within the wavelength range between 190 nm and 230 nm is generated and qualified both in terms of information technology and in terms of actuator technology, both on an information technology basis and with a communications technology objective, as a transmission medium for the spatial or area-wide broadband/ultra-broadband supply of stationary and portable or mobile users or user groups within closed and semi-closed rooms and objects or areas, as well as on an actuator technology basis and with an objective in terms of actuator technology as an effective medium for the contactless and health-harmless bacterial and viral inactivation or disinfection of the room air of closed and semi-enclosed rooms and objects or areas, as well as of the surfaces of the objects stationary or movable inside the rooms and objects;
based on the generation of a UV (ultraviolet) photonic radiation field of defined polarization signature as well as defined geometric, temporal and amplitude signature within the wavelength range between 190 nm and 230 nm, a signal-specific access network is configured for access to both the information technology target radiation field and/or signal signatures and the actoric technology target radiation field and/or signal signatures;
within the wavelength range between 190 nm and 230 nm, a spectrally broadband radiation field with a constant radiation power spectrum is generated, wherein the broadband radiation field generation is effected in such a way that the radiation field with a constant radiation power spectrum is generated by means of a broadband source “Q” or by means of two or more wavelength-shifted narrowband radiation field sources “Qsn” with “Qs1” . . . “Qsm” with frequency-rigid radiation power spectra “fQsn” . . . “fQsm” or by means of two narrowband radiation field sources “Qs1” and “Qs2” with the controllable radiation power spectra “fQs1” and “fQs2”, wherein the wavelength-related cascading of the sources “Qsn”, consisting of the sub-sources “Qs1” . . . “Qsm” with the frequency-rigid radiation power spectra “fQsn” with “fQs1” . . . “fQsm” depending on their respective power spectral characteristics is effected in such a way that the frequency-dependent superposition of the related radiation power spectral components ensures the constancy of the radiation power over the wavelength range between 190 nm and 230 nm;
by means of a transmission member “T1”, consisting of the sub-transmission members “T1-1” and “T1-2”, two linearly polarized wave fields “SLP1” and “SLP2”, preferably spatially orthogonally linearly polarized to each other, are selected from the preferably divergent unipolarized source field within the wavelength range between 190 nm and 230 nm;
the linearly polarized, preferably spatially orthogonally to each other linearly polarized fields “SLP1” and “SLP2” are converted by means of a transmission member “T2”, consisting of the sub-transmission members “T2-1” and “T2-2”, into circularly polarized fields in the manner in that by means of the transmission member “T2-1” the linearly polarized wave field “SLP1” is converted into a circularly polarized wave field, preferably left-hand circularly polarized wave field “SZP1” and by means of the transmission member “T2-2” the linearly polarized wave field “SLP2” is converted into a circularly polarized wave field, preferably right-hand circularly polarized wave field “SZP2”;
the linearly polarized, preferably spatially orthogonally to each other linearly polarized wave fields “SLP1” and “SLP2” generated at the output-side gates of the transmission members “Tn1”, consisting of the transmission members “Tn1-1” and “Tn1-2” and/or consisting of the transmission members “T1-1” and “T1-2” for the case n=1, form the input variables of the radiation-coupled transmission members “Tn21”, consisting of magneto-optically or electro-optically active transmission members “Tn2MO-1” and/or “Tn2EO-1”, and the input variables of the radiation-coupled transmission members “Tn22”, consisting of magneto-optically or electro-optically active transmission members “Tn2MO-2” and/or “Tn2EO-2”, in that the transmission member “T1-1” generating the linearly polarized wave field signature “SLP1” is coupled to a transmission member “Tn2MO1”/“Tn2EO-1”, and the transmission member “T1-2” generating the linearly polarized wave field signature “SLP2” is coupled to a transmission member “Tn2MO-2”/“Tn2EO-2”, wherein the transmission member “Tn2MO-1”/“Tn2EO-1” is formed by means of a transmission member “Tn2MO-1”/“Tn2EO-1” or by means of several sub-transmission members “SmTn2MO-1”/“SmTn2EO-1” with m=2 to j, and the transmission member “Tn2MO-2”/“Tn2EO-2” is formed by means of a transmission member “Tn2MO-2”/“Tn2EO-2” or by means of several sub-transmission members “SmTn2MO-2”/“SmTn2EO-2” with m=2 to j;
the coupling of the transmission member “T1-1”/“T1-2” with the transmission member “Tn2MO-1”/“Tn2MO-2” or “Tn2EO-1”/“Tn2EO-2” is effected by means of radiation field-coupled and/or radiation field-based coupling members;
by means of the transmission system “Tn2”, in each case including the transmission members “Tn2-1” as well as “Tn2-2”, in each case consisting of the transmission members “Tn2MO” or “Tn2EO” and consisting in each case of one transmission member or several sub-transmission members, forming the transmission members “Tn2MO-1”/“Tn2MO-2” with spectral bandpass characteristic “fnB” according to the condition “fnB”<<“Bf” and magnetically both discretely and continuously controllable band center frequency “fnM” or by means of the transmission system “Tn2”, in each case including the transmission members “Tn2-1” as well as “Tn2-2”, each consisting of the transmission members “Tn2MO” or “Tn2EO” and each consisting of one transmission member or several sub-transmission members, forming or resulting in the transmission members “Tn2EO-1”/“Tn2EO-2” with spectral bandpass characteristic “fnB” according to the condition “fnB”<<“Bf” and electrically both discretely and continuously controllable band center frequency “fnM”, preferably consisting of one transmission member or several sub-transmission members, forming or resulting in the transmission members “Tn2MO-1”/“Tn2MO-2” with spectral bandpass characteristic “fnB” according to the condition “fnB”<<“Bf” and magnetically both discretely and continuously controllable band center frequency “fnM”, preferably consisting of the sub-transmission members “SmT2MO-1”/“SmT2MO-2” with m=1 to j, preferably with m=1 to 4 sub-transmission members:
“S1Tn2MO-1” and “S1Tn2MO-2”
“S2Tn2MO-1” and “S2Tn2MO-2”
“S3Tn2MO-1” and “S3Tn2MO-2”
“S4Tn2MO-1” and “S4Tn2MO-2”
discretely or continuously controllable, preferably discretely controllable transmission filters with narrow-band spectral bandpass characteristics of high flank steepness as well as high degree of wide-range selection are generated;
the output-side wave fields of the transmission member “Tn2”, consisting of the sub-transmission members “SmT2MO-1”/“SmT2MO-2” with m=1 to j, preferably with m=1 to 4 sub-transmission members comprise the polarization signature of circular polarization, in that the output-side wave fields of the sub-transmission members “SmT2MO-1” and “SmT2MO-2” are polarized in the same or opposite sense to one another, preferably in opposite senses, wherein the sub-transmission members “SmT2MO-1” preferably generate a left-hand circular polarization signature and the sub-transmission members “SmT2MO-2” preferably generate a right-hand circular polarization signature;
the spectral bandwidths of the transmission spectra of the sub-transmission members “SmTn2MO-1”/“SmTn2MO-2” are dimensioned equal or unequal, preferably equal to each other;
the sub-transmission members “SmTn2MO-1”/“SmTn2MO-1” are dimensioned with m=1 to j, preferably with m=1 to 4 mutually different coupling spectra, wherein the band center frequencies of the coupling spectral ranges have to satisfy the conditions fkMm>>fkBm and fkMm+1>fkMm as well as fkBm<2 (fkMm+1−fkMm) with m=1 to j;
the coupling spectrum “fn2K-1” or “fn2K-1” of the transmission member “Tn2MO-1” or of the sub-transmission members “SmTn2MO-1” is discretely dimensioned or continuously controlled, preferably discretely dimensioned, while satisfying or maintaining the conditions fkMm>>fkBm and fkMm+1>fkMm and fkBm<2 (fkMm+1−fkMm) with m=1 to j, preferably with m=1 to 4;
the coupling between the transmission members “T1-1”/“T1-2” and “SmTn2MO-1”/“SmTn2MO-1” is effected as a parallel coupling in such a way that m, with m=1 to j, preferably m=4, sub-transmission members “SmTn2MO-1” are coupled by means of the radiation field coupled and/or the radiation field based coupling member “Km1/2-1”, with m=1 to j, preferably m=1 to 4, with the transmission member “T1-1”, and m, with m=1 to j, preferably m=4, sub-transmission members “SmTn2MO-2” are coupled to the transmission member “T1-2” by means of the radiation field-coupled and/or the radiation field-based coupling member “Km1/2-2”;
on the coupling-related basis of the radiation coupling, the transmission member “Tn2MO-1”/“Tn2MO-2” is coupled to a further transmission member “Tn3MO-1”/“Tn3MO-2”, wherein the transmission member “Tn3MO-1”/“Tn2MO-2” is formed by means of a transmission member “Tn3MO-1”/“Tn3MO-2” or by means of a plurality of transmission-topologically series-coupled or parallel-coupled, preferably transmission-topologically parallel-coupled sub-transmission members “SmTn3MO-1”/“SmT32MO-2” with m=2 to k;
by means of the transmission member “Tn3MO-1”/“Tn3MO-2”, each consisting of one transmission member or several sub-transmission members, forming the transmission members “Tn3MO-1”/“Tn3MO-2” with spectral bandpass characteristic “fnB” according to the condition “fnB”<<“Bf” and electrically both discretely and continuously controllable band center frequency “fnM”, preferably consisting of the sub-transmission members “SmT3MO-1”/“SmT3MO-2” with m=1 to j, preferably with m=1 to 4 sub-transmission members:
“S1Tn3MO-1” and “S1Tn3MO-2”
“S2Tn3MO-1” and “S2Tn3MO-2”
“S3Tn3MO-1” and “S3Tn3MO-2”
“S4Tn3MO-1” and “S4Tn3MO-2”
discretely or continuously controllable, preferably discretely controllable transmission filters with narrow-band spectral bandpass characteristics of high flank steepness as well as high degree of wide-range selection are generated;
the sub-transmission members “SmTn3MO-1”/“SmTn3MO-2” are dimensioned with m=2 to k mutually different coupling spectra, wherein the band center frequencies of the coupling spectral regions must satisfy the conditions fkMm>>fkBm and fkMm+1>fkMm as well as fkBm<2 (fkMm+1−fkMm) with m=1 to j;
the coupling spectrum “fn2K-1” or “fn2K-2” of the transmission member “Tn3MO-1”/“Tn3MO-2” or of the series-coupled or parallel-coupled, preferably parallel-coupled sub-transmission members “SmTn3MO-1”/“SmTn3MO-2” forming the transmission member “Tn3MO-1”/“Tn3MO-2” is discretely dimensioned or continuously controlled while fulfilling or complying with the conditions fkMm>>fkBm and fkMm+1>fkMm as well as fkBm<2 (fkMm+1−fkMm) with m=1 to j;
the coupling of the transmission members “Tn2MO-1” and “Tn3MO-1” or “Tn2MO-2” and “Tn3MO-2” is effected while fulfilling or complying with the conditions to be taken as a basis fkMm (Tn2MO-1)=fkMm (Tn3MO-1) or fkMm (Tn2MO-2)=fkMm (Tn3MO-2) and the conditions fkBm (Tn2MO-1)=fkBm (Tn3MO-1) or fkBm (Tn2MO-2)=fkBm (Tn3MO-2) and fkMm+1−fkMm of “Tn2MO-1”=fkMm+1−fkMm of “Tn3MO-1” or fkMm+1−fkMm of “Tn2MO-2”=fkMm+1−fkMm of “Tn3MO-2”;
the transmission systems “Tn2MO” and “Tn2MO-1/Tn2MO-2” as well as “Tn3MO” and “Tn3MO-1”/“Tn3MO-2”, consisting of the sub-transmission systems:
“S1Tn3MO-1” and “S1Tn3MO-2”
“S2Tn3MO-1” and “S2Tn3MO-2”
“S3Tn3MO-1” and “S3Tn3MO-2”
“S4Tn3MO-1” and “S4Tn3MO-2”
and
“S1Tn3MO-1” and “S1Tn3MO-2”
“S2Tn3MO-1” and “S2Tn3MO-2”
“S3Tn3MO-1” and “S3Tn3MO-2”
“S4Tn3MO-1” and “S4Tn3MO-2”
form a multi-circuit gyromagnetic coupler with several, preferably four, spectrally static or spectrally controllable, preferably spectrally controllable transmission passes;
the transmission system “Tn3MO-1”/“T3MO-2” radiation-coupled by means of a transmission member “T3”, consisting of the sub-transmission members “T3-1” and “T3-2” with the functionality of polarization signature synthesis, preferably of a linear polarizer with statically impressed transmission function, with a transmission system “Tn4”, consisting of the transmission members “Tn4MO” or “Tn4EO”, in each case comprising the transmission members “Tn4-1” and “Tn4-2” and consisting of one transmission member or a plurality of sub-transmission members, preferably consisting of the associated sub-transmission members “SmT4MO-1”/“SmT4MO-2” and/or the associated sub-transmission members “SmT4EO-1”/“SmT4EO-2” with m=1 to j, preferably with m=1 to 4 sub-transmission members:
“S1Tn4MO-1”/“S1Tn4EO-1” and “S1Tn4MO-2”/“S1Tn4EO-2”
“S2Tn4MO-1”/“S2Tn4EO-1” and “S2Tn4MO-2”/“S2Tn4EO-2”
“S3Tn4MO-1”/“S3Tn4EO-1” and “S3Tn4MO-2”/“S3Tn4EO-2”
“S4Tn4MO-1”/“S4Tn4EO-1” and “S4Tn4MO-2”/“S4Tn4EO-2”
the resulting oscillation planes of the linearly polarized fields generated in each case on the output side of the transmission system “Tn4” are offset with respect to the linearly polarized fields on the input side both discretely and continuously controllably with respect to one another in such a way that the linearly oscillating wave fields on the output side of the transmission system “Tn4” are generated with a variable or controllable angular offset of 0 to 90 angular degrees with respect to the linear oscillation direction of the wave fields on the input side of the transmission system “Tn4”;
the wave fields generated at the output gates of the transmission system “Tn4”, consisting of the transmission members “Tn4MO-1”/“Tn4EO-1” and “Tn4MO-2”/“Tn4EO-2”, form the input signals of signal- and diagram-forming transmission components, preferably of the transmission components for the temporally and spatially controllable radiation diagram preprocessing “SV” and on this basis the input wave fields or input signals of the radiation diagram synthesizing sub-transmission members “SVD” of the radiation diagram pre-processing system “SV”.
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