| 摘要 |
<p>1,190,067. Digital facsimile transmission systems. XEROX CORP. 28 Sept., 1967 [3 Oct., 1966 (4)], No. 44135/67. Headings H4F and H4P. The time-bandwidth product of binary signals, e.g. facsimile signals, is reduced at a transmitter by run-length encoding, the signals being coded into words the lengths of which depend on the statistical distribution of the runlengths of the data. The system is such that run lengths which occur frequently are represented by short words. At the transmitter, Fig. 1, binary data from scanner 101 is fed to a unit 103 comprising a shift register associated with circuitry which determines whether the length of a sequence of 0-bits is 1, 2, 3, or more than 3 bits long and feeds units 107, 105. The register output feeds unit 109. Unit 109 comprises a shift register/ counter, its output feeding a buffer store 119 and transmission unit 121. The stages of the register in 109 are monitored by units 107, 105. The bits from 103 are counted at 109 and when the counter contains a certain bit pattern the pattern is shifted one or more steps and, under control of units 105, 107, counting continues until another certain pattern is reached, whereupon the count is again shifted. Thus the generated code word length increases for each additional n 0-bits from 101, n varying with the run length. Run lengths consisting of 1-bits are encoded in a different code. The codes used for 0 and 1 bit runs are shown in Fig. 8 (not shown). Each run code transmitted is preceded by the code word for a run one bit long of 1 or 0 state as appropriate to the run. The receiver, Fig. 2, comprises an encoder 201 identical to that at the transmitter, driven by binary data on line 209. At the start of a run register 109 contains the code word of a one bit run in 1-bit or 0-bit code as appropriate (e.g. each line scan starts with one or more 0-bits) and register 203 is filled by a like number of bits from input buffer 213. If the registers do not contain the same words, gate 205 detects the inequality and drives unit 207 to print a 1 or 0 bit as appropriate at printer 215. The bit from 207 also drives encoder 201 so that register 109 now shows the second code word of the appropriate 1- or 0-bit code. If there is still inequality a second bit is printed, the encoder stepped and the cycle repeated. Hence register 109 exhibits successively the successive words of the appropriate 1 or 0 code-register 109 being shifted after every n bits, as at the transmitter, and such shifting causing corresponding shift in register 203-until gate 205 determines equality of the registers' contents. Unit 207 then causes printing of the other bit state and sets encoder 201 to encode according to the other code.</p> |
