Multi-channel HDTV system

US 5,128,791 A
Filed: 08/13/1990
Issued: 07/07/1992
Est. Priority Date: 08/13/1990
Status: Expired due to Term

First Claim

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1. A television signal transmitting system comprisinga first filter bank comprising first and second finite impulse response filters with finite precision filter coefficients, said first filter being a low pass filter with a substantially diamond-shaped pass band and said second filter being a high pass filter with a substantially diamond-shaped stop band,said first filter bank receiving and decomposing a high resolution progressive video sequence in a two-dimensional vertical-time representation to produce an interlaced video sequence and a deinterlacing video sequence,said interlaced video sequence being capable of forming a low resolution television image in a low resolution television receiver,said interlaced and said deinterlacing video sequences being capable of being recombined by a second filter bank comprising third and fourth finite impulse response filters with finite precision filter coefficients to perfectly reconstruct said high resolution video sequence in said two-dimensional vertical-time representation for use by a high resolution television receiver, said third filter being a low pass filter with a substantially diamond-shaped pass band and said fourth filter being a high pass filter with a substantially diamond-shaped stopband,wherein the transfer functions of said first, second, third, and fourth filters are two dimensional and dimensionally non-separable.

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Abstract

A filter bank comprising first and second finite impulse response diamond-shaped filters with finite precision filter coefficients is used to convert a high definition progressive video sequence in a vertical-time representation into an interlaced sequence and a deinterlacing sequence. The interlaced sequence may be used by a low resolution television receiver to display a low resolution television image. The interlaced and deinterlacing sequences may be recombined to perfectly reconstruct the progressive high definition video sequence which then may be used by a high definition television receiver. Thus, the inventive system has the advantage that it enables a single high definition video sequence to be utilized by both high definition television equipment and lower resolution television equipment so that an existing base of consumer television equipment is not rendered obsolete by the introduction of a high definition television sequence.

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22 Claims

1. A television signal transmitting system comprisinga first filter bank comprising first and second finite impulse response filters with finite precision filter coefficients, said first filter being a low pass filter with a substantially diamond-shaped pass band and said second filter being a high pass filter with a substantially diamond-shaped stop band,said first filter bank receiving and decomposing a high resolution progressive video sequence in a two-dimensional vertical-time representation to produce an interlaced video sequence and a deinterlacing video sequence,said interlaced video sequence being capable of forming a low resolution television image in a low resolution television receiver,said interlaced and said deinterlacing video sequences being capable of being recombined by a second filter bank comprising third and fourth finite impulse response filters with finite precision filter coefficients to perfectly reconstruct said high resolution video sequence in said two-dimensional vertical-time representation for use by a high resolution television receiver, said third filter being a low pass filter with a substantially diamond-shaped pass band and said fourth filter being a high pass filter with a substantially diamond-shaped stopband,wherein the transfer functions of said first, second, third, and fourth filters are two dimensional and dimensionally non-separable.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
- - 2. The system of claim 1 wherein said first, second, third, and fourth filters are paraunitary.
  - 3. The system of claim 1 wherein said first, second, third and fourth filters are linear phase.
  - 4. The system of claim 3 wherein said first, second, third and fourth filters are linear phase and have left-right and top-bottom symmetry.
  - 5. The system of claim 3 wherein said first, second, third and fourth filters are circular symmetric.
  - 6. The system of claim 1 wherein said first filter bank includes first and second quincunx subsampling means associated with said first and second filters, respectively.
  - 7. The system of claim 1, said second filter bank includes first and second upsampling means associated with said third and fourth filters, respectively.
  - 8. The system of claim 3 wherein said first filter has a spatio-temporal transfer function of the form ##EQU9## and wherein said second filter has a spatio-temporal transfer function of the form ##EQU10## wherein a₀, a₁ and a₂ are finite precision numbers.
  - 9. The system of claim 4 where said first filter has a spatio-temporal transfer function of the form ##EQU11## and wherein said second filter has a spatio-temporal transfer function of the form ##EQU12## wherein a, b, c, and d are finite precision numbers.
  - 10. The system of claim 2 wherein said first filter has a spatio-temporal transfer function of the form ##EQU13## and wherein said second filter has a spatio-temporal transfer function of the form ##EQU14## wherein a₀, a₁ and a₂ are finite precision numbers.
  - 11. The system of claim 1 wherein said system further comprises a third filter bank comprising fifth and sixth finite impulse response filters with finite precision coefficients for receiving said interlaced television signal in a two-dimensional vertical-time representation and for outputting first and second low resolution progressive video signals, said fifth filter being a low pass filter with a substantially diamond-shaped pass band and said sixth filter being a high pass filter with a substantially diamond-shaped stop band.

12. A television system comprisinga first filter bank comprising first and second finite impulse response filters with finite precision filter coefficients, said first filter being a low pass filter with a substantially diamond-shaped pass band and said second filter being a high pass filter with a substantially diamond-shaped stop band,said first filter bank receiving a high resolution video sequence in a two-dimensional vertical-time representation and producing first and second low resolution video sequences in a vertical-time representation,said first low resolution video sequence being capable of forming a low resolution television image on a low resolution television receiver, andmeans for recombining said first and second low resolution video sequences, said recombining means comprising a second filter bank including third and fourth finite impulse response filters with finite precision filter coefficients to substantially perfectly reconstruct said high resolution sequence in said two-dimensional vertical-time representation for use by a high resolution television receiver, said third filter being a low pass filter with a substantially diamond-shaped pass band and said fourth filter being a high pass filter with a substantially diamond-shaped stop band,wherein the transfer functions of said first, second, third, and fourth filters are in two-dimensional form and are dimensionally non-separable.
- View Dependent Claims (13, 14, 15, 16, 18)
- - 13. The system of claim 12 wherein said high resolution video sequence is a progressive sequence and said first and second low resolution video sequences are an interlaced and a deinterlacing sequence, respectively.
  - 14. The system of claim 12 wherein said high resolution video sequence is an interlaced sequence and said first and second low resolution video sequences are progressive sequences.
  - 15. The system of claim 12 wherein said first, second, third and fourth filters are linear phase.
  - 16. The system of claim 12 wherein said first, second, third and fourth filter are paraunitary.
  - 18. The system of claim 14 wherein said first low resolution video sequence is an interlaced sequence, said second low resolution video sequence is a deinterlacing sequence, and said high resolution video sequence is a progressive sequence.

17. A television signal receiving system comprisinga synthesis filter bank comprising first and second finite impulse response filters with finite precision filter coefficients, said first filter being a low pass filter with a substantially diamond-shaped pass band and said second filter being a high pass filter with a substantially diamond-shaped stop band,said first filter receiving and filtering a first low resolution low frequency video sequence in a two-dimensional vertical-time representation to form a first output sequence in a vertical-time representation,said second filter receiving and filtering a second low resolution high frequency video sequence in a two-dimensional vertical-time representation to form a second output sequence in a vertical-time representation,said first and second low resolution video sequences being formed as result of the decomposition of a single high resolution video sequence,said filter bank comprising means for combining said first and second output sequences to perfectly reconstruct said high resolution video sequence and said transfer functions of said first and second filters are two dimensional and dimensionally non-separable.

19. A filter bank for use in a high definition television system comprisinga first, low pass, finite impulse response, liner phase filter having a transfer function of the form ##EQU15## and a second, high pass, finite impulse response, linear phase filter having a transfer function of the form ##EQU16## wherein a₀, a₁ and a₂ are finite precision numbers, said first and second filters of said filter bank cooperating to process one or more video sequences inputted to said filter bank, such that the video sequence is perfectly reconstructed, and said transfer functions of said first and second filters being two dimensional and dimensionally non-separable.

20. A filter bank for use in a high definition television system comprisinga first, low pass, finite impulse response, linear phase filter having a transfer function of the form ##EQU17## and a second, high pass, finite impulse response, linear phase filter having a transfer function of the form ##EQU18## wherein a, b, c, and d are finite precision numbers, said first and second filters of said filter bank cooperating to procress one or more video sequences inputted to said filter bank, such that the video sequence is perfectly reconstructed and said transfer functions of said first and second filters being two dimensional and dimensionally non-separable.

21. A filter bank for use in a high definition television system comprisinga first, low pass, finite impulse response filter having a transfer function of the form ##EQU19## and a second, high pass, finite impulse response filter having a transfer function of the form ##EQU20## wherein a₀, a₁ and a₂ are finite precision numbers, said first and second filters being paraunitary,said first and second filters cooperating to process one or more video sequences inputted to said filter bank, such that the video sequence is perfectly reconstructed, and said transfer functions of said first and second filters being two dimensional and dimensionally non-separable.

22. A television signal transmitting system comprisinga first filter bank comprising first and second finite impulse response filters with finite precision filter coefficients, said first filter being a low pass filter with a substantially diamond-shaped pass band and said second filter being a high pass filter with a substantially diamond-shaped stop band,said first filter bank receiving and decomposing a high resolution progressive video sequence in a multi-dimensional representation to produce an interlaced video sequence and a deinterlacing video sequence,said interlaced video sequence being capable of forming a low resolution television image in a low resolution television receiver,said interlaced and said deinterlacing video sequences being capable of being recombined by a second filter bank comprising third and fourth finite impulse response filters with finite precision filter coefficients to perfectly reconstruct said high resolution video sequence in said multi-dimensional representation for use by a high resolution television receiver, said third filter being a low pass filter with a substantially diamond-shaped pass band and said fourth filter being a high pass filter with a substantially diamond-shaped stopband,wherein the transfer functions of said first, second, third, and fourth filters are multi-dimensional and dimensionally non-separable.

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Current Assignee
Regents of the University of California (University of California)
Original Assignee
Bell Communications Research, Inc. (Telefonaktiebolaget LM Ericsson)
Inventors
Vetterli, Martin, LeGall, Didier J.
Primary Examiner(s)
Groody, James J.
Assistant Examiner(s)
LEE, MICHAEL

Application Number

US07/566,831
Time in Patent Office

694 Days
Field of Search

358/141, 358/12, 358/138, 358/133, 358/142, 358/135, 358/140, 358/137, 358/11
US Class Current

348/469
CPC Class Codes

H03H 17/0266   Filter banks

H04N 19/112   according to a given displa...

H04N 19/136   Incoming video signal chara...

H04N 19/187   the unit being a scalable v...

H04N 19/30   using hierarchical techniqu...

H04N 7/0152   using spatial or temporal s...

Multi-channel HDTV system

First Claim

3 Assignments

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Abstract

112 Citations

22 Claims

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Multi-channel HDTV system

First Claim

3 Assignments

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0 Petitions

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Accused Products

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Abstract

112 Citations

22 Claims

Specification

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Solutions

Use Cases

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