According to the MPEG standard, variable length packetized elementary streams (PES) of data are arranged into fixed length transport packets for transmission. Each MPEG packet comprises a 4 byte header followed by 184 bytes of payload (188 byte packet) . The header includes a sync byte (corresponding to 47 HEX) and a 13 bit packet identifier (PID) . The 188 byte transport packets are multiplexed for transmission over any suitable transmission medium. The proposed United States standard for advanced television (ATV) , which includes both high definition television (HDTV) and lower than HDTV resolution signals, contemplates the transmission of MPEG transport packets using a digital multilevel VSB transmission system. The VSB transmission system in both terrestrial and 2/4/8/16-level cable modes is characterized by a data frame illustrated in FIG. 1. The frame comprises two data fields of 313 data segments each with each data segment comprising 832 multilevel symbols.

The first data segment in each field comprises a data field sync segment and each data segment is headed by a four symbol data segment sync followed 828 data and FEC (forward error correction) symbols. The field and segment sync symbols facilitate recovery of the data in the ATV receiver and provide timing signals that identify

the beginning of each frame and segment. Each field sync segment also includes information identifying the VSB mode.

The transmission is via suppressed carrier modulation. Three hundred and ten kilohertz from the lower band edge, a small DC pilot is added to the signal for use by the VSB receiver in achieving carrier lock.

All payload data is randomized to insure that random data is transmitted even when constant data is being supplied to the system. The data and FEC bytes are interleaved for added protection against burst errors.

The symbol rate is 4.5/286 MHz x 684 which is approximately 10.76 MHz. It will be appreciated that the first term, 4.5/286 is the NTSC horizontal scan rate.

All transmitted signals are multilevel. The sync symbols are always 2-level (binary) . In the terrestrial mode, 8 level trellis-coded symbols (3 bits per symbol) are transmitted while for the cable mode, 16/8/4/2-level symbols (4/3/2/1 bits per symbol, respectively) are used.

These are referred to as trellis coded 8 VSB for the terrestrial mode and 16/8/4/2 VSB for the cable mode. In the 16 VSB cable mode, each segment includes four 2-level sync symbols plus 414 data bytes (828 x 4 ÷ 8) . In the 8

VSB cable and trellis modes, each segment includes four

2-level sync symbols plus 310.5 data bytes. In the 4 VSB cable mode, each segment includes four 2-level sync symbols plus 207 data bytes. In the 2 VSB cable mode, each segment includes four 2-level sync symbols plus

103.5 data bytes.

The use of MPEG transport packets for the VSB

transmission results in an unnecessary redundancy and a reduction of data capacity since both MPEG sync bytes and

VSB data segment sync symbols are included. That is, the purpose of the MPEG sync byte is to identify the beginning of a packet. The same information can be derived from the segment sync in VSB. Moreover, the information can be derived very conveniently due to the

VSB parameters, i.e. symbols/segment and bits/symbol.

Objects of the Invention

A principal object of the invention is to provide a novel ATV transmission and reception system.

Another object of the invention is to provide an improved system for transmission and reception of digital data.

A further object of the invention is to provide a novel digital transmission system utilizing MPEG transport packets.

A still further object of the invention is to avoid the above-mentioned inefficiency in utilizing MPEG transport packets in VSB transmissions. Brief Description of the Drawings

These and other objects and advantages of the invention will be apparent upon reading the following description in conjunction with the drawings, in which:

FIG. 1 is an illustration of a VSB frame format;

FIG. 2 is a simplified block diagram of a transmitter constructed in accordance with the invention;

FIGS. 3A and 3B represent the MPEG transport packets as modified in accordance with one aspect of the invention;

FIG. 4 is a simplified block diagram of a receiver for receiving the signals from the transmitter of FIG. 2;

FIGS. 5A, 5B, 5C and 5D illustrate the arrangements of the received signals and the reformulated MPEG transport packets for the FIG. 4 receiver;

FIG. 6 is a simplified block diagram of an alternate form of a receiver; and

FIG. 7 is a block diagram illustrating the MPEG sync reinsertion technique used in the FIG. 4 receiver. Description of the Preferred Embodiment

Referring to FIG. 2, an ATV signal source 10 is coupled to an MPEG video compressor 12 and to an audio compressor 14, both of which in turn supply an MPEG transport multiplexer 16. Transport multiplexer 16 is also supplied with the output of an auxiliary data source 13. The outputs of MPEG video compressor 12 and audio compressor 14 are packetized elementary streams (PES) of variable length packets of compressed video and audio data complete with their own headers and synchronizing information. These are well known in the art. In the MPEG transport multiplexer 16, the PES signals and auxiliary data are formatted into fixed length MPEG data transport packets of 188 bytes, including a 4 byte header having a 1 byte MPEG sync. The multiplexed compressed MPEG transport signals are supplied to a block 18 labeled MPEG sync byte remover where the MPEG sync byte is removed from each MPEG transport packet. In this regard, it will be appreciated that the functions of blocks 16 and 18 may be combined to directly produce the 187 byte packets developed at the output of MPEG sync byte remover

18. The output of block 18 is applied to a block 20, which includes a symbol encoder, an R-S encoder, an interleaver and a randomizer where the compressed data is encoded and processed as multilevel symbols (depending upon the VSB mode) and applied to a multiplexer 24. The

R-S encoder adds 20 R-S error correction bytes to each transport packet which therefore comprises 207 bytes

(188-1 +20) . A sync generator 22 adds data segment sync

(DSS) and field sync (FS) to the encoded symbols for providing an output at multiplexer 24 having the format shown and previously discussed in connection with FIG. 1.

This output is then applied to a block 26 where a pilot

(DC offset) is inserted. The output of pilot inserter 26 is coupled to a VSB modulator 28 and that in turn is coupled to an RF upconverter 30 for transmission of the signal. As previously mentioned, the VSB transmission is of a suppressed carrier form, with the pilot being inserted at the frequency of the suppressed carrier.

FIG. 3A illustrates a conventional MPEG transport packet which consists of 188 bytes including a 4 byte header at the beginning of the packet, with the first byte of the header being the MPEG sync byte. The header also includes a 13 bit packet identifier (PID) and the complete packet includes the 4 byte header and a 184 byte payload.

In FIG. 3B, the MPEG transport packet of FIG. 3A is shown with the MPEG sync byte removed as shown in FIG. 2.

This 187 byte packet consists of a 3 byte header and a

184 byte payload. The 20 FEC bytes are added to this modified MPEG transport packet by symbol encoder 20 for a

total of 207 bytes for transmission. Each transport packet therefore constitutes a R-S error correction block of 207 bytes. The modified transport packets are assembled into the VSB frame format consisting of two fields of 313 data segments with 832 symbols per data segment including a four symbol data segment sync by multiplexer 24 for eventual transmission. The VSB field syncs occupy the first data segment in each field (see

FIG. 1) .

An ATV receiver is shown in FIG. 4. A tuner 32 tunes the received RF signal from the transmitter and supplies it to an IF synchronous detector block 34 where the signal is detected. In this block, carrier recovery is performed on the small pilot carrier by an FPLL circuit (not shown) . The output of detector 34 is supplied to an A/D converter 36 which in turn supplies a symbol decoder block 38, the output of which comprises received transport packets without the MPEG sync byte and which is coupled to an MPEG sync reinsertion circuit 40.

A/D 36 supplies a sync and timing circuit 42 where the repetitive data segment syncs are detected from the synchronously detected random data. A properly phased

10.7 MHz symbol clock is developed for controlling the

A/D converter 36, and data segment sync (DSS) and field sync (FS) are applied to symbol decoder block 38 for recovering the binary data that the symbols represent .

The VSB mode signal is recovered in symbol decoder block

38 and supplied to sync and timing circuit 42. In the processing in symbol decoder block 38, FEC is performed and the signal is deinterleaved and derandomized. Timing

control signals are applied to MPEG sync reinsertion block 40 for enabling the proper reinsertion of the MPEG sync byte in each processed transport packet. The output of MPEG reinsertion block 40 is therefore in the standard

MPEG transport packet format (188 bytes including a 4 byte header) which is applied to a transport demultiplexer 44 for separation of the MPEG compressed video and the compressed audio (as well as any auxiliary data) into the var _* iable length PES packets. The video

PES packets are applied to an MPEG video decompressor 46 which in turn supplies a D/A converter 48, the output of which constitutes the video information. The audio PES packets from transport demultiplexer 44 are applied to an audio decompressor 50 and thence to a D/A converter 52.

To summarize, the transmitted data is recovered at the receiver in response to the field and data segment sync signals, and a timing signal is developed that is used to identify the MPEG sync byte reinsertion points. The 20 FEC bytes are used for error correction and the signal is deinterleaved and derandomized. Then the MPEG sync byte is reinserted in each error corrected 187 byte packet to provide the standard 188 byte MPEG packets which are processed by the transport demultiplexer.

FIGS. 5A, 5B, 5C and 5D illustrate, respectively, the input signals to the decoder block 38 and the corresponding output signals to the transport demultiplexer 44 for the 4, 8, 16 and 2 VSB signals with the various numbers on the figures representing bytes. The upper signal of each pair represents two segments of the input VSB signal each comprising 4 DSS symbols and

828 data symbols, whereas the lower signal represents the reconstituted 188 byte MPEG transport packets with the 1 byte MPEG sync reinserted, plus the 20 FEC bytes. For the four VSB system in FIG. 5A, both the data segment sync and the MPEG sync are 1 byte clock in duration.

Because of this 1:1 relationship, each data packet is delayed by one byte to permit reinsertion of the MPEG sync byte (represented by the letter "S" in FIGS. 5A-5D) .

In FIG. 5D, which represents a 2 VSB signal, the data segment sync is one-half byte clock in duration and two full data segments are required for one 207 byte transport packet. In this mode, each packet is delayed one byte clock for every two data segments to permit appropriate reinsertion of the MPEG sync byte . In

FIG. 5C, each data segment sync is two byte clocks in duration and each data segment represents two 207 byte transport packets. Consequently, the first data packet is delayed by one byte clock for insertion of the MPEG sync byte. Since the second data packet occurs before another DSS, the second data packet is delayed by an additional type clock for insertion of the MPEG sync byte. This pattern is repeated for subsequent data segment pairs. In FIG. 5B, the data segment sync is 1.5 byte clocks in duration two data segments represent three data packets. The first data packet is delayed one byte clock for MPEG sync insertion. The second packet begins before another DSS so that the packet is delayed an additional byte clock for insertion of the MPEG sync byte. The third packets begins after the next DSS which delays the input by 1.5 byte clocks. Insertion of the

third MPEG sync byte causes a third byte clock delay, but since the input has been delayed by 1.5 byte clocks, the net delay is only 1.5 byte clocks (3-1.5) . This sequence repeats at the beginning of the next packet as an additional one byte clock delay is added to the output for MPEG sync byte insertion for a total of 2.5 bytes.

An additional 1.5 byte clock delay DSS delay is added to the input yielding a net delay of 1 byte clock (2.5-1.5) .

FIG. 6 is another embodiment of the invention. The

VSB segment sync and field sync are used in the symbol decoder block 38' of this receiver to develop the data, i.e. the binary data represented by the encoded symbols.

A data valid signal and a begin 207 byte packet signal are developed by sync and timing circuit 42' for transport demultiplexer 44 ' . The begin 207 byte packet signal marks the beginning of each of the 207 byte packets of the VSB signal and the data valid signal is inactive during the 20 FEC bytes of each packet. It will be understood that the begin 207 byte packet signal will be generated by symbol decoder block 38' in response to the DSS and FS as follows:

For 2 VSB - at the beginning of every other data segment.

For 4 VSB - at the beginning of every data segment.

For 8 VSB - three evenly spaced times during each pair of data segments, starting with the beginning of the first data segment.

For 16 VSB - twice each data segment, starting at the beginning of each segment.

The data valid signal supplied to demultiplexer 44 '

identifies the valid 187 bytes of each packet, the 20 FEC bytes, if present, being ignored. With this receiver arrangement, the MPEG sync byte is not inserted, which results in a further simplification. While the transport demultiplexer 44 ' is not a standard MPEG unit and needs to be set up to operate with these signal inputs, the design is well within the ability of one of ordinary skill in the art.

In FIG. 7, the MPEG sync reinsertion block 40 of

FIG. 4 is divided into its constituent blocks. They consist of an MPEG sync pattern generator 54 which supplies its output (47 HEX) to the A input of a multiplexer 56. The B input of multiplexer 56 is supplied from a programmable delay circuit 58 that receives data from symbol decoder block 38. Delay circuit 58 receives an input D from circuit 42 that varies in accordance with the VSB mode as described above. The delay produced by delay circuit 58 is thus variable with input D and in accordance with the diagrams in FIGS. 5A, 5B, 5C and 5D, is determined by the VSB mode. The timing signal from sync and timing block 42 controls the operation of multiplexer 56 so that the MPEG sync pattern is supplied at the appropriate time to the data stream to reconstruct the MPEG transport packets for application to the transport demultiplexer 44.

What has been described is a novel system for transmitting and receiving data signals preferably utilizing MPEG transport packets. It is recognized that numerous changes in the described embodiment of the invention will be apparent to those skilled in the art

without departing from the scope of the invention which is defined in the claims.