Hierarchically modulated OFDM communication from a satellite-based transmitter with reduced secondary data loss from clipping
First Claim
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1. A method for transmitting high priority and low priority digital data in hierarchical modulation from an earth-orbiting satellite, the method comprising the steps:
- encoding the high priority digital data with a forward error correcting code to provide encoded high priority digital data;
performing an Inverse Fast Fourier Transform on the encoded high priority digital data to provide high priority, orthogonal frequency division multiplexed (OFDM) symbols each comprising a first predetermined number of samples in an original high priority sample order, each of the first predetermined number of samples having a sample power;
encoding the low priority digital data with a forward error correcting code to provide encoded low priority digital data;
performing an Inverse Fast Fourier Transform on the encoded low priority digital data to provide low priority orthogonal frequency division multiplexed (OFDM) symbols each comprising a second predetermined number of samples in an original low priority sample order, wherein the second predetermined number is less than the first predetermined number;
selecting one of the high priority OFDM symbols and one of the low priority OFDM symbols;
selecting a plurality of samples of the selected high priority OFDM symbol equal in number to the second predetermined number, wherein the selecting is in accordance with a first consistent, deterministic rule using sample power comparisons to eliminate one or more of the highest powered samples of the high priority OFDM symbol from selection;
associating each sample of the selected low priority OFDM symbol with a different one of the selected samples of the selected high priority OFDM symbol according to a second consistent, deterministic rule relating the original low priority sample order to the original high priority sample order;
deriving a combined OFDM symbol based on the selected high priority OFDM symbol by (1) leaving unchanged each sample of the selected high priority OFDM symbol having no associated sample of the low priority OFDM symbol and (2) superimposing each sample of the selected low priority OFDM symbol onto its associated sample of the selected high priority OFDM symbol to provide a combined sample having a sample power equal to the sum of the sample powers of the associated samples so combined;
incorporating the combined OFDM symbol in a radio frequency OFDM signal, whereby the encoded low priority digital data is modulated as secondary data on the encoded high priority digital data, as primary data, in hierarchical modulation; and
transmitting the radio frequency OFDM signal on a plurality of orthogonal radio frequency carriers.
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Abstract
High priority data and low priority digital data are transmitted as primary and secondary data in hierarchically modulated, orthogonal frequency division multiplexing (OFDM) from an earth-orbiting satellite. To enable the transmitter amplifier to be operated with less back-off from saturation without clipping, the low priority OFDM symbols have fewer samples than the high priority OFDM symbols, and the high priority samples on which the low priority samples are superimposed are selected according to a first deterministic rule using sample power comparisons of the high priority samples to concentrate the low priority samples on those high priority samples having lower (optimally, the lowest) sample power. The low priority samples are distributed on the selected high priority samples according to a second deterministic rule relating the original low priority sample order to the original high priority sample order.
29 Citations
12 Claims
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1. A method for transmitting high priority and low priority digital data in hierarchical modulation from an earth-orbiting satellite, the method comprising the steps:
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encoding the high priority digital data with a forward error correcting code to provide encoded high priority digital data; performing an Inverse Fast Fourier Transform on the encoded high priority digital data to provide high priority, orthogonal frequency division multiplexed (OFDM) symbols each comprising a first predetermined number of samples in an original high priority sample order, each of the first predetermined number of samples having a sample power; encoding the low priority digital data with a forward error correcting code to provide encoded low priority digital data; performing an Inverse Fast Fourier Transform on the encoded low priority digital data to provide low priority orthogonal frequency division multiplexed (OFDM) symbols each comprising a second predetermined number of samples in an original low priority sample order, wherein the second predetermined number is less than the first predetermined number; selecting one of the high priority OFDM symbols and one of the low priority OFDM symbols; selecting a plurality of samples of the selected high priority OFDM symbol equal in number to the second predetermined number, wherein the selecting is in accordance with a first consistent, deterministic rule using sample power comparisons to eliminate one or more of the highest powered samples of the high priority OFDM symbol from selection; associating each sample of the selected low priority OFDM symbol with a different one of the selected samples of the selected high priority OFDM symbol according to a second consistent, deterministic rule relating the original low priority sample order to the original high priority sample order; deriving a combined OFDM symbol based on the selected high priority OFDM symbol by (1) leaving unchanged each sample of the selected high priority OFDM symbol having no associated sample of the low priority OFDM symbol and (2) superimposing each sample of the selected low priority OFDM symbol onto its associated sample of the selected high priority OFDM symbol to provide a combined sample having a sample power equal to the sum of the sample powers of the associated samples so combined; incorporating the combined OFDM symbol in a radio frequency OFDM signal, whereby the encoded low priority digital data is modulated as secondary data on the encoded high priority digital data, as primary data, in hierarchical modulation; and transmitting the radio frequency OFDM signal on a plurality of orthogonal radio frequency carriers. - View Dependent Claims (2, 3, 4, 5, 6)
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7. A method of receiving a hierarchically modulated orthogonal frequency division multiplexed (OFDM) radio frequency transmission comprising a series of combined OFDM symbols comprising encoded low priority digital data hierarchically modulated onto encoded high priority digital data, wherein each combined OFDM symbol comprises a first predetermined number of samples each corresponding, in an original combined sample order, to a selected sample of a high priority OFDM symbol having the first predetermined number of samples and containing the high priority encoded digital data, wherein each of a second predetermined number, less than the first predetermined number, of the samples of the combined OFDM symbol is a combined sample having a sample power equal to a sum of (1) the sample power of the corresponding sample of the high priority OFDM symbol and (2) the sample power of an associated sample of a low priority OFDM symbol having the second predetermined number of samples and containing the encoded low priority digital data, wherein the correspondence of the selected samples of the high priority OFDM symbol is characterized by a first consistent, deterministic rule using sample power comparisons to eliminate one or more of the highest powered samples of the high priority OFDM symbol from selection, and wherein the association of each of the selected samples of the low priority OFDM symbol with a particular one of the selected samples of the high priority OFDM symbol is characterized by a second consistent, deterministic rule relating an original low priority sample order to an original high priority sample order in the combined OFDM symbol, the method comprising the steps:
deriving combined OFDM symbols from the received, hierarchically modulated OFDM transmission;
copying the combined OFDM symbols and storing the copies;
demodulating the combined OFDM symbols to recover the encoded high priority digital data;
decoding the encoded high priority digital data to recover the transmitted high priority digital data;
copying and re-encoding the high priority digital data;
performing an Inverse Fast Fourier Transform on the encoded high priority digital data to provide reconstructed high priority OFDM symbols corresponding to the combined OFDM symbols;
selecting one of the reconstructed high priority OFDM symbols and the stored copy of its corresponding combined OFDM symbol;
subtracting each sample of the selected high priority OFDM symbol from a corresponding sample of the selected stored copy of its corresponding combined symbol to provide a Diff sample, the provided Diff samples comprising a Diff symbol;
according to the first consistent, deterministic rule, determining which samples of the reconstructed high priority OFDM symbol are associated with a sample of a low priority OFDM symbol;
selecting the Diff samples corresponding to the samples of the reconstructed high priority OFDM symbol that are determined to be selected for an associated sample of a low priority OFDM symbol and distributing the selected Diff samples into the original low priority sample order according to the second consistent deterministic rule to provide a recovered low priority OFDM symbol; and
demodulating and decoding the low priority OFDM symbol to recover the transmitted low priority digital data.- View Dependent Claims (8, 9, 10, 11, 12)
Specification
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Current AssigneeAptiv Technologies AG
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Original AssigneeDelphi Technologies, Inc. (BorgWarner Incorporated)
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InventorsMarrah, Jeffrey J., Walker, Glenn A., Dibiaso, Eric A.
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Primary Examiner(s)Ngo; Ricky
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Assistant Examiner(s)KAO, WEI PO ERIC
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Application NumberUS12/362,712Publication NumberTime in Patent Office767 DaysField of Search370/208, 370/319, 370/344, 370/480, 370/529US Class Current370/344CPC Class CodesH04B 7/18523 Satellite systems for provi...H04L 1/007 Unequal error protection fo...H04L 27/2604 Multiresolution systems by ...H04L 27/2614 Peak power aspectsH04L 27/2626 Arrangements specific to th...H04L 27/2647 Arrangements specific to th...H04L 27/3488 Multiresolution systems
