DE4244835A1 - Telefax or colour television image coding system - Google Patents

Abstract

The coding system shortens the transmission time for black and white digital or numeric longitudinal coding, by using the same codewords for both black and white and for different numbers or characters, with the input sequence of black and white used as the discrimination criteria. When several successive white lines are coded, the transmission time is reduced further by providing the coded number of white lines before or after the white line codeword. During gray coding the gray stages or binary codewords are sub-divided, with deliberate redundancy where characters occur successively, with subsequent transmission in the same manner as the white lines. The transmission time is reduced for colour image transmission by code multiplexing, with the PAM coded information DC biased. The sum alternating current thus varies in phase by up to 90 degrees.

Description

Technical field

The present invention is concerned with a method of coding and transmission of gray tones in faxes.

State of the art

Fax machines are in standard groups depending on the transmission time assigned. Groups 1 and 2 are with a point by point scan already overtaken by Group 3 devices. The latter represent a digital one Transmission system in which the image sampling points of equal brightness summarized in an uninterrupted sequence and into a code word be united. Such processes are called one-dimensional. The MHC is one of them. The two-dimensional process is on the same Principle built. With this, a reference line is first scanned and only the difference in the following line coded the reference line. The MRC process works on this principle. Then there is the MMR code, after which a coded reference line a larger number of subsequent lines are encoded two-dimensionally. At the run length encoding is one for each number of pixels per line special binary code set for white and black, e.g. B. 1 white = 000111, 1 black = 010, 2 white = 0111, 2 black = 11,. . . 20 white = 0001000, 20 black = 00001101000. Such coding goes up to Pixel number 63. Then again from the beginning with an additional section code word started for white and black. For the transfer of these coded numbers, in particular the phase difference or. Amplitude phase difference modulation used.

In the gray scan, the gray values were divided into gray levels and the gray values were quantized in gray scales divided and into more or less dense patterns of white and black Pixels implemented. It is like the dither printing process is known, a corresponding gray gradation perceived by the eye. These white and black pixels were then transmitted to the receiver.

Presentation of the invention

A disadvantage with this type of coding and transmission was the long Duration that was necessary for the transfer and transfer of colored images. Since so far several carriers at the Color transfer needed are due to mutual interference Disorders such as B. Cross Color, Cross Luminance occurred.

The object of the invention is to provide such a coding the information in a shorter time than before with at least the same Transfer security to transmit. This is achieved by the quantized gray image value with any code to the receiver is transmitted and only in this in white / black pixels after the Dither process is converted. One becomes expedient for the transfer provide for a multi-level coding process.

In the description below, first, for better understanding Procedures for coding and transmitting images and templates are shown.

Brief description of the drawings

Fig. 1 overview diagram of a fax machine.

Fig. 2, an alternating current code in which the characteristic states are marked by the amplitudes of the half waves. Multi-value coding is achieved by two alternating currents which are phase-shifted by 90 ° and which are added for the transmission.

Fig. 3 is a multi-value alternating current code, in which several total alternating currents are provided, the frequency of which is always half the frequency higher than the primary alternating current.

Fig. 4 is an AC code in which the coding is determined by the period and the amplitude size of the half-waves.

Fig. 5 shows an overview of phase jumps by period.

Fig. 6 circuit for generating periods and amplitude levels.

Fig. 7 is a graph of the addition of phase levels.

Fig. 8 is a vector diagram for the representation of phase jumps when changing an amplitude with 90 ° phase-shifted alternating currents when they are added.

Fig. 9 generation of amplitude levels.

Fig. 10 representation of the binary code elements for 6 lines for code multiplex coding.

Fig. 11 + 12 representation of operational characteristics when combining several lines.

Fig. 13 is a quaternary code.

Fig. 14 shows a color television receiver for code division multiplex reception.

Fig. 15 vibration curves for the color difference signals with and without DC bias with PAM and stair signals.

Fig. 16, 17, 18, 19, 22, coding of color television signals

Fig. 20, 21, a narrow-band information channel between television channels

Fig. 23, 24, 25 reordering code words

Fig. 27, 28, 33 encoding and decoding constant run lengths

Fig. 29, 30, 31, 32 coding of grays

Ways of Carrying Out the Invention

In Fig. 1 an overview is shown of a facsimile machine. The reading unit L has the task of converting the original to be transmitted into analog electrical signals. They are then converted into digital signals in the encoder Cod. The Mo modem is intended for transmission. The AS interface unit adapts to the telephone network. The received signals go to the decoder Decod via the AS and are converted back to their original form in this unit. The paper is then recorded in the recording unit Az. A central control ZSt controls the remote copying system and coordinates the remote copy transmission. Control takes place from control panel B.

The invention relates to the coding and transmission of the pixels. According to the invention, run length coding is carried out in such a way that the respective number of white or black pixels is encoded digit by digit becomes. Are z. B. 28 white pixels successively scanned, so there is a coding 2 white and subsequently 8 white. Will be in the episode 6 black pixels are scanned, the number 6 is encoded black. So it is a code for the digits 0 to 9 white and for the digits 0 up to 9 black required. 20 combinations are required for these digits. Of course, the special characteristics, such as the start and end mark (EOL) or the EOP, MCF or other criteria are encoded. For coding these 20 digits and the criteria required for operation can be quite simple binary or multi-valued coding can be provided. At 20 Combinations are 5 bits according to the teletype alphabet No. 2 required. You can use it to code 32 combinations or criteria. Since there are a maximum of 4 digits when z. B. per line 1728 Pixels are available, you can use the other combinations also 2-digit Encode digits in the manner by looking at the thousands that occur combined with the associated hundreds to form a code, e.g. B. the numbers 10, 11, 12,. . . 17. For coding a maximum of 1728 pixels  then you get by with 3 codes. A distinction between white and black is not necessary because of the following digit coding state whether the two-digit number is too white or black belongs. Should z. B. 1728 white pixels are encoded, so first 17 and subsequently 2 white and 8 white coded. Through the 2 and 8 white it is certain that 17 belongs to white. According to the existing standard begins each line with a white run length. This norm remains the invention is not affected. This invention can also apply to the MRC or MMR code or similar code for both the reference line and the following lines are used with the deviations from the reference line, by the number or the difference in number of the pixels as well be encoded digit by digit.

Since there are always alternating numbers for white and black in the run length method, this sequence can be provided as a criterion or indicator. It is then possible to use the same code words for white and black. You can then z. B. First send all white run length numbers and then all black run length numbers. The transition from white to black must then be marked by a criterion or indicator, that is, by a special code word. If the coding is of the same number, then all code words must have the same number of digits. 1 pixel should then z. B. with 001, 12 pixels with 012. The previously used phase difference or amplitude phase difference modulation can also be used for the transmission itself. Further encodings are explained below. A duobinary half-wave code is shown in FIG . The amplitudes of half-waves serve as code elements - if DC freedom is necessary, periods will be provided for this - two alternating currents of the same frequency which are phase-shifted by 90 °. Both are added for the transmission, so that only one alternating current is present during the transmission. In the example, the characteristic states are (0) = aP11, (1) = aP1, aP2,. . . (2) = aP3,. . . With this principle, the number of bits can be increased significantly if one z. B. provides an arrangement according to FIG. 3. One or more encoding alternating currents are thus provided, the frequency or frequencies of which each increase by half the original frequency, e.g. B. at an original frequency of 1000 Hz 1500 Hz. For coding, 2 coding alternating currents can be provided with 90 ° phase shift at 1500 Hz. With 2 total coding alternating currents one would achieve 10 bits with one period or 1½ periods. An amplitude / phase code can also be provided. Such is shown in FIG. 4. The phase is assigned two characteristic states by the half-wave period and the amplitudes of these half-waves. With 2 phase and 2 amplitude characteristics, 2 to 4 to 2 and 4 to 4 to 4 combinations are obtained. To achieve freedom from direct current, the positive and negative half-wave is required for a characteristic state. The number of phase characteristics is also a transmission problem, taking the runtime into account. In FIG. 5 5 phase characteristic states are provided. The normal phase is f = 360 units. If you switch to 405 units and this phase shift remains, you must switch back to a half-period or period of 360 units in the next half-period or period. A circuit how such phase / amplitude encodings can be generated is shown in FIG. 6. The counter Z is controlled with pulses of a predetermined frequency, which are generated in the oscillator Osc. With the outputs Z1, Z2,. . . the half or period duration of the rectangular pulses to be generated is then determined. The control which period duration or which output is to take effect is carried out with the encoder Cod. If the half or period duration of the output Z1 is to be effective, the gate G3 is marked via g3. If the output Z1 is reached, the gate G3 becomes effective and thus controls the electronic relay ER. The start of the rectangular pulse was marked with A. The amplitude of the rectangular pulse is determined by the voltage applied to ER via (A) (++), (+), (-), (-). At the output of ER, rectangular pulses with a predetermined period and amplitude are then obtained. If you want sinusoidal half-waves for the transmission, the square-wave pulses are applied to the line via a low-pass filter TP, the transformer U and possibly via a filter Fi.

If only narrow bands are available at higher frequencies, it is advisable to carry out the amplitude and / or the phase changes of the characteristic states in stages, so that very narrow frequency bands are obtained. Is z. For example, as shown in FIG. 7, the normal phase or period duration 360 units and if this is shortened 4 times by 10 units, there is a difference in the 4th shortening compared to the 4 × 360 units of 40 units. From f = 1 / T you get the phase step frequency if you assign a certain time to the 360 units. If you switch back to the normal period of 360 units after the 4 shortened periods, there is an ongoing phase shift of 40 units. This is explained in more detail in European patent application publication number 0329 158. On this basis, you can make an advantageous coding by z. B. 3 phase jumps - normal phase, leading and lagging phase shift - and 3 different period numbers. The phase jump levels are then also contained in the periods. If you take 100, 150 and 200 as the period numbers and a phase shift leading and lagging by 45 °, you have 9 coding levels. With 2 digits you already have 9 to the power of 2 combinations, with 3 digits 729 combinations. There are various variations in number and phase in this regard. The change in a characteristic state is shown in the example by a change in amplitude. The amplitude can of course also be provided as a step. With a phase jump of 45 °, there is a phase change of 0.45 ° for every period in 100 periods. As with the burst in television, there is also a comparison phase with the receiver. B. be required. With a 64 KHz channel bandwidth, a smaller number of periods will be provided. The frequency change is expediently made at the zero crossing, and tolerances can also be permitted both in the number of periods and in the phase.

If the amplitudes of two coding alternating currents which are phase-shifted by 90 ° are provided as the characteristic states, then each change of characteristic state can also be carried out here by means of a multiplicity of amplitude stages. It is known that when such alternating currents are added, phase jumps also occur in the case of amplitude jumps. In FIG. 2 such coding alternating currents are illustrated with duo-binary coding. FIG. 8 shows a vector diagram of such coding alternating currents with binary coding. The characteristic states are Uk + U and Uk, Vk + V and Vk. If the amplitude changes, phase jumps of q can occur. In order to avoid such, the amplitude changes are carried out in stages, denoted in the figure with Stu and Stv. In the Fig. 9 shows a circuit for generating such stages. In the example, the change is made using resistors R1, R2,. . . which are switched into the AC circuits by means of an electronic relay eS. The control takes place at the zero crossing, by means of a limiter B generating synchronization pulses with which the encoder that switches the electronic relay is controlled.

For the transmission one can also combine several lines and transmit code multiplex. One could then also distribute the EOL and other characters on the combined lines. The code multiplexed summary can e.g. B. done by binary-coded the digits of the individual lines, synchronized and summarized in parallel and combined with a multi-valued code word. In Fig. 10 6 lines are summarized according to this method. The code word S1 then consists of the binary code elements 100100, S2 from 001000, S3 from 100011, etc. The start and the end as well as possibly other identifiers can be distributed over all lines. Examples of this are shown in FIGS. 11 and 12. These characteristics can be marked by one or more parallel code words. In Fig. 11 there are 4x6 binary code elements. In FIG. 4 lines 12 are shown, wherein 4 x 4 code elements are provided for the start and end identifier. You can also assign a special code to the last line. A further reduction in the transmission time can be achieved by combining lines of the same coding length or similar coding length in a code-multiplexed manner with the interposition of a memory, a line marking being required for each line. For A4 templates it is e.g. B. 1100 lines. 1100 combinations must be provided for the line coding. However, these can also be used as EOL indicators. The code-multiplexed summary of the digits or numbers is expediently carried out with a higher value, e.g. B. quaternary octonary, coding. An example of a quaternary coding is shown in FIG . For coding 256 combinations, 8 bits are required, which can be represented with 8 binary code elements. You can also combine the 8 code elements into 4 dibits, so that only 4 code elements are required for coding the 8 bits. In the example of digit coding, 32 combinations, i.e. 5 bits, are required for 10 white, 10 black for the thousands and other indicators. With quaternary coding, 2 digits will always be combined in series or in parallel, so that dibits can always be formed. With 4-level coding, you get 4 to 5 with 5 digits, i.e. 1024 combinations, i.e. 10 bits. If binary half-wave code elements are provided in FIG. 2, 5 half-waves are required for each of the two alternating coding currents. All lines with only white can have their own short code. You can also add a code word to the white lines and then only list the line numbers of the white lines and give them a special identifier at the end of the white lines. This method of transmitting the white lines is applicable to all known coding and transmission methods. White lines do not need to be printed out, so that you only have to make a call at the receiving station. Such electronic circuits are known from circuits of electronic typewriters, so they are not discussed in more detail.

Sometimes it is necessary for the transfer of originals and images Coding and transmitting gray values. In a known related The various grayscales are encoded exclusively with shown white and black pixels. It is based on the Printing technology known dither method used. Be at this the grayscale in more or less dense patterns of white and black Pixels implemented. The scanning unit evaluates according to the analog voltage values received by the reflective surface the grayscale, e.g. B. 16, and save this. A white area corresponds to gray value 0 and a black value to gray value 16. One Coding and transmission can again be based on the principle of run lengths done, you can also z. B. 1, 2,. . . 16 encode and transmit, or the respective analog value. To shorten the transmission time you can combine 2 or 3 grayscale into a code word. The respective gray value can also be transferred analogously by using the Voltage values or pulses, which correspond to PAM pulses in pulse durations and converted into rectangular pulses with the help of an electronic relay. The length of the respective rectangular pulse then corresponds to the height of the tapped voltage value. You can then use a filter Establish coding alternating current. The half or period duration of the half waves then contain the information. This principle is in the European Patent application publication number 0 329 158 already disclosed.

For the coding and transmission of colored images and templates, e.g. B. For faxes and color television, complex processes have been used so far been. For faxes, it is advisable to use the color separations of the primary colors to be transferred, because the recipient's paper often consists of 3 stacked Photo layers exist. Color television encodings are from the NTSC-PAL and SECAM systems and from my patent US 4,675,721 and the patent applications DE P 32 23 312, P 32 26 382 and P 37 09 451 known. In the present method, all of the color transfer is done relevant signals with only one carrier or the carrier is provided immediately for information coding.

If only the color separations are coded and transmitted, limit values must be transmitted for green, red and blue. A smaller number of levels - with digital coding - is sufficient for faxes than for television. At z. B. 16 shades of gray per color, one could summarize the 3 values of the basic colors codemultiplex. This requires 12 bits that can be encoded with the codes already listed, such as. B. with the half-wave code of FIG. 2 or with a phase code in connection with a number of periods or amplitude levels. The narrow-band coding can also be provided if, for. B. phase levels and / or amplitude levels and / or levels in the number of z. B. provides periods. These encodings can of course also be used if the color difference signals and the luminance signal are possibly also transmitted in a code-multiplexed manner. If the code-multiplexed information via radio z. B. for television purposes, where the RF transmitter is simply modulated with the coding alternating current. The receiver is then designed like a superhet radio receiver, one of which is shown in FIG. 14. After the demodulator DM, only one decoder DC is required. Further details can be found in European patent application publication number 0329158.

In previous television systems, for. B. the color signals RY and BY analog modulated onto a carrier of the same frequency, which were 90 ° out of phase with each other. Depending on the polarity of the respective color voltage, the carrier has made corresponding phase jumps. Both carriers were added for the transmission. The sum vector, which represented the saturation of the color, determined the color by its angle in the color circle. In Fig. 15 are analog signals from RY and BY and in Fig. 16 there is an associated vector diagram. A disadvantage of such a transmission is that the small values are affected by the noise. The voltage values can only be made positive by means of a direct current bias, shown in broken lines in FIG. 15, so that a vector diagram as shown in FIG. 17 is produced when the carriers are added. As with PAM, it is useful to sample the color signals and design them as stair signals. If the luminance signal is also sampled synchronously with the color signals, the color signals being sampled alternately, and carrier alternating currents which are 90 ° out of phase with respect to one another are modulated, the entire CVBS signal can be transmitted by adding the carriers with an alternating current. In FIG. 18, the stepped-PAM signals, and in Fig. 19 is a vector diagram for this purpose. With a DC bias of all PAM pulses, a phase shift of 90 ° can never occur with vector changes, as can be seen from FIG. 8. In the case of intermediate storage, the pulses can be mixed in such a way that 1 color pulse occurs for every 3 or 4 luminance pulses. With this type of coding, the information is represented by the size of the sum vector and by the phase position thereof. If a narrow frequency band is required for the transmission, the method of FIG. 8 can be provided.

Fax can also be introduced to certain professions on television, e.g. B. for lawyers to receive new fundamental judgments, for tax consultants, for doctors, etc. B. done in such a way by providing the sound channel 2 for these purposes. The NF output of this channel would have to be connected to sockets so that the fax machine could be connected at any time. Such a connection could also be made for a fee. The sound carrier could then also be encoded directly as a narrowband information carrier. - Of course, one could also use the other known frequency and time division multiplexing methods for the second audio channel for faxes. - So much can be encoded with the sound carrier that you can encode other information besides the 2nd tone. Are z. B. 100 periods are provided per code element, 57 420 code elements can be made with a sound carrier of 5.742 MHz. An additional channel can also be accommodated between the television channels in such a way that a carrier is provided between the audio channel 2 and the following television channel, which carrier is also used for the narrow-band phases and / or amplitudes and / or different multiplicity of periods. The bandwidth for such a carrier can be kept free by a corresponding series resonance circuit, as can be seen from FIG. 20. In the figure, the series resonance curve is denoted by RR, the carrier by BTZ. In FIG. 21, the basic arrangement is shown of a narrowband channel between 2 television channels. The carrier frequency is approximately 195.25 MHz. Small frequency fluctuations are always present due to the gradual phase or amplitude changes. This principle is already described in more detail in the published patent application DE 40 25 026.

A method is shown in FIG. 22 in which the analog or digital information of two channels can be transmitted with only one alternating current. In the example, it is the luminance signal Y and the color difference signals RY and BY. The Y signal and the two color beard signals are alternately pulse amplitude modulated and shaped into staircase signals, which is already known. This is shown in FIGS. 22a and 22b. Both signal sequences are each modulated onto an alternating carrier current of the same frequency, but which are 90 ° out of phase with respect to one another. The carrier frequency, in the example 22d, is expediently synchronized with the tap frequency and is an integral multiple of the tap frequency. The two carrier alternating currents FIGS . 22c and 22d are added. This produces a total alternating current Su Fig. 22e with the same frequency as that of the two carriers. When the staircase signals are modulated onto the respective carrier alternating currents, and when the two carriers are added, phase jumps occur. The phase relationship of the total alternating current to a comparison phase contains the information of the staircase signals of FIGS. 22a and 22b in connection with the respective amplitude. This total alternating current can be transmitted to the receiving point in this form. A comparative alternating current corresponding to the burst is necessary when evaluating the phase position. Such an evaluation is e.g. B. known from the PAL system.

In the color image transmission z. B. the 3rd Sizes of the primary color separations for green, red and blue or the luminance signal Y and the chromatic signals such as B. the color difference signals R-Y and B-Y transfer. Quadrature amplitude modulation is often used for the transmission intended. This can be done through an immediate transfer of the Coded signals are made by using the amplitudes of half-waves as code elements or periods are used which are phase-shifted to 2 by 90 ° AC currents of the same frequency can be distributed. For the transfer the two alternating currents added. With an indirect transmission be, e.g. B. the PAM-modulated signals by the amplitudes of rectangular pulses, Stair signals or by the amplitudes of half waves or periods of alternating currents coded and each to 2 continuous Sequences lined up and on 2 carrier alternating currents phase-shifted by 90 ° modulated. These are then added for the transmission. Since at the Color image coding always 3 values to be transmitted, such as B. the primary color separations green, red and blue or the luminance signal Y and the chrominance signals such as B. the color difference signals R-Y and B-Y is taken into account the valency requires a cyclical exchange, the z. B. looks like this: Basic color separations gr / rt, rt / bl., bl / gr, gr / rt,. . . Luminance signal and color difference signals Y / R-Y, Y / B-Y, Y / R-Y,. . . With the basic color separations is an equal value and the luminance signal and Color difference signals are valued at 2.1.

The coding or total alternating currents can also be transmitted alternating currents be provided. Are DC biases in the PAM taps provided, these are dimensioned so that the useful signals are above the noise or interference level.  

For white ws and black sw the same code words for the run lengths it is possible to use due to the conditions. There must be every line always start with a white barrel length. Starts the line with the Color black, the white run length zero is sent first. also the code word EOL is at the beginning of a page and at the end of each line sent. This is also the synchronization of the white / black sequence that is particularly important in the evaluation. At the number coding was the frequency of occurrence of the lengths considered. If what is written is to be transferred, do so with black very often small barrel lengths, such as 2, 3, 4. These were correspondingly assigned small code words such as 11, 10, 011. Consequently becomes the same when using the same code words for white and black Consider frequency. According to the previous table are white the numbers 2 to 7 are equally common, while black and 2 are the most common occurrence. In the case of black, the shortest are therefore according to the invention Code words for the numbers 2 and 3, these are in white z. B. used for the numbers 4 and 5. Half of the encodings are then not necessary anymore. The coding of the larger numbers becomes one do not use black at all anymore, because these are 12 digits during these are only 8 digits for white. With a larger horizontal Resolution will of course be an appropriate frequency adjustment make. If you go from 8 to 16 pixels per millimeter, so the 2sw is increased to 4sw pixels, d. H. the number 4 comes up black then most often before. The following are coding options for some of the most common numbers.

On the transmitting and receiving side, the coding and evaluation devices only need to be wired appropriately in order to obtain the desired coding or run lengths. In FIGS. 23, 24 and 25 some circuits for the assignment of the code words are presented to the predetermined run-length. After evaluating the EOL mark, there is always a white run length or a zero. With a circuit, such are known, the sequence is then switched white / black after evaluation of the EOL mark and a corresponding potential, e.g. B. high h applied. If the number 1 was evaluated in FIG. 23 and the sequence is just white ws, then the gate has 1w h / h, so that it becomes effective and the number marks white ws1. If the number 5 has been evaluated and the sequence is black sw, the gate is 5s twice hh, so that the number black sw5 is then marked.

In FIG. 24 shows a circuit for the assignment of the evaluated code words in different figures for white and black according to the table on the left. The code words black sw 1 to 6 are also provided for the numbers 2 to 7. Is z. B. the code word 1sw and the sequence is marked white ws, the gate G1 becomes effective and the number 2 marked white 2w. If the code word 5sw is evaluated and the sequence is marked in white sw, the gate 10 becomes effective and the number is marked in black 5s. If the code word is marked white 2ws and the sequence marked black sw, the gate 14 becomes effective and the number 7 marked black 7s.

An example is shown in FIG. 25, in which a switchover to different run length numbers takes place depending on the respective resolution 8 or 16 points per millimeter. Such a switchover can of course be carried out using a dedicated chip. The table shows examples of assignments for 8 points on the left and 16 mm on the right. Is z. B. the resolution 8, is applied to 8 potential h at the receiver. If the code word 3sw is evaluated, then the gate G1 becomes effective, which applies such potential to G3 and G4 that G3 becomes effective with a white marking and G4 with a black sequence marking and the numbers mark white ws4 or black sw3. If a different potential becomes necessary as a result of G1, a potential reversal gate can be switched on behind G1. For example, a NOT gate. If the resolution 16 is marked, G2 becomes effective and subsequently the gate G5 or G6 depending on ws or sw. Esx is then marked with the number ws7 or sw7 (see table).

In practice, the new coding in connection with group 3 will be applied in the transition stage in such a way that a switchover to the new coding is provided. The unused code words would then not come into effect. You could of course also retrofit existing devices with the help of additives. A possible principle of a switchover is shown in FIG . The outputs of ws 0, 1, 2. . . and sw 0, 1, 2,. . . are each led to 2 gates. These gates are only effective depending on a potential that is applied to one of the two gates via the changeover switch U. If the coding of group 3 is to be provided, the switch is in position 3b; if the new coding is to be used, switch U is in position 3n. Is z. B. marked white 1 and the switch U is at 3b, the gate G4 has potential once over ws1 and once over U / 3b, so that the coding of group 3 takes effect. If, on the other hand, the switch is at U / 3n, there is potential at both inputs of the gate G3, so that it can then take effect. As from the Gi. 23 to 25 can be seen, the coding ws 1 can then be assigned to any number. Is z. If the coding sw0 is not required, no gate for the new operating mode is switched on. This is just one example of a switch.

A further reduction in the transmission time can be achieved by providing the code word for white or black only once when coding with only white or black lines and then subsequently the code word for the number of the respective lines, such as, for. B. the code word for 1728 white and subsequently the number of white lines z. B. 83. Typewriter pages normally have a white space between the lines of 4 mm. With a resolution of 8, this would result in 32 lines. Since white lines occur very often, one could e.g. B. provide a short code word for 1728. It is of course an advantage if the text line has the same horizontal line as the insert. The detection of the number of white lines can e.g. B. in such a way that a counter is controlled with the white line code word until a code word for black sw comes. The output then marked on the counter is evaluated, coded in the central control and either stored or sent directly to the transmission path via modem and connection unit. In FIG. 27, the coding white line is connected to the counter Z ws1728, so that the counter is incremented by an output at each coding. The meter itself is connected with its outputs to the central control unit ZSt. The black code words sw are connected via a monostable switch that is delayed on. Such a connection is also made directly to the central control ZSt. The meter reading is now determined immediately, if necessary saved and coded. The counter is switched back to the starting position via sw, MS. The central control gives the code word for white lines and subsequently the code word for the number of white lines via the transmission path to the receiver via encoder, modem and the interface unit. On the reception side, when the code word "white line" is received, the output that corresponds to the number of white lines is marked on a counting arrangement. The recording unit is then controlled by the central control unit; in the case of white lines, there is then an immediate step on until the number of stored white lines is switched. In FIG. 28, a principle of the comparison is shown between the stored white line number and switched white number. The counter Z2 is started via J as soon as white lines are marked. In the example, 32 lines are marked. A connection is therefore connected to a gate G1, on which the 32nd output of the counter is located via the other input. As soon as the counter Z2 has reached the output 32, the further switching of the counter is interrupted with the potential now occurring at the output of G1 via stop. The counter Z3 is also controlled by the recording unit with the switching of the white lines via ZJ. When the output 32 on the counter Z3 is reached, the gate G2 then becomes effective, and the forwarding of the white lines is then stopped.

In the case of gray transmission, the principle of using the same code words for white and black brings considerable time savings. However, these are not yet satisfactory. Further possibilities of gray coding and transmission are recorded below. Up to now, as was also shown in FIG. 29, in order to encode the grayscale only with white and black pixels, the semitones have been converted into more or less dense patterns of black and white pixels. The scanning unit evaluates the analog voltage values. The white pixel is level 0 and the black level 16 or, with better resolution, level 64. The stages are then translated into corresponding patterns, such as some shown in Figures 29a-d. In this way, the information can then be processed further as a black or white pixel. It can be seen from this that only short run lengths have to be transmitted, so that the transmission is very time-consuming. In the following exemplary embodiments, ways are now shown of how the transmission time can be shortened in the gray image transmission. A number of pixel voltages are shown in FIG . 1 is black and corresponds to 16 levels, 2 = 14, 3 = 8 levels, etc. In the case of a gray image, there is very little white and black, so that the levels for white and possibly also for black levels are coded and transmitted separately. - The pixel stages are only converted using the dither method at the receiver. One will therefore first line by line the first 4 stages as shown in Fig. 32 and then code and transmit the remaining u stages. As a code you will e.g. B. provide the code used in group 3. In the Fig. 32 are for. B. up to pixel voltage 6 below 4 no values available. The value 4 would then z. B. assign sw2 = 11. As already described according to a further feature of the invention, since 4 occurs six times in succession, an encrypted number 6 is provided behind the code word for 4, 4 comes z. B. 96 times in succession, so the encrypted number for 96 behind the code word for 4. In this way it is possible to quickly transfer a lot of line information. The same can also be provided for stages 13, 14, 15 and 16. For gray images, the main information will be between levels 5 and 13. One can of course transfer the difference of the stages to the final stage 16 in exactly the same way. For traffic between large companies or authorities, it is easily possible to provide your own microprocessors, which then calculate the most time-saving transmission coding. Temporary storage is always advisable.

Another possibility of shortened transmission is to lock the 16 steps, as is usual with telex, and thus to transmit them. A binary code would require 2 to 4 code elements. Of course you could use the run length coding of group 3 here. If the same code words occur in succession, the number of the following identical code words could again be sent to the receiver by a number. With this method the transmission time can be shortened again. This effect can be increased if redundancy is deliberately introduced into the code, e.g. B. by providing a 5-digit binary code for the 16 levels. An example of this is shown in FIG. 30. With these 5 digits, as with teletype code No. 2, 32 combinations are possible, designated 1-32 in FIG. 30. The 5 code elements are then transmitted with 2 lines, once 2 and once 3 combined. In FIG. 30, the code elements of the columns 4 and 5 and the other for the code elements of columns 1, 2 and 3 are provided for the one line. In the example, the code words that are black in column 5 are to be used for coding the 16 levels. Then only the code elements black / black and black / white occur. The shortest code of group 3, namely 2sw and 3sw, can then be provided for these. With these two coding sequences of one or the other coding occur very often, so that the effect of encrypting and transmitting the number of sequences often occurs. The 3-digit code words in columns 1, 2 and 3 occur twice, so that 8 code words must be provided for the 3 columns. If columns 3, 4 and 5 and 1, 2 are combined into one line, only 4 code words are required per line.

In Fig. 31, a two-line transmission can also be provided and the 8 used as the starting line. For pixels 1, 2,. . . 7 against 0 would then result in the values 0.0,0,0,0,0,2 and against 16 would result in the values 8,6,0,0,6,4,0.

The values 8 to 0 and 8-16 can also be transmitted analogously to FIG. 17, or 2 pixels can be transmitted simultaneously. RY would then be the pixels 1, 3, 5,. . . and BY the pixels 2, 4,. . . be assigned. One could also transmit 2 × QAM at the same time if one assigned the one to the upper sideband and the other to the lower sideband of a carrier and filtered out one of the two filters and merged the non-filtered out bands. Such a principle is e.g. B. disclosed in U.S. Patent 2,907,830. This principle can of course also be used in the transmission of color television signals.

If a great deal of writing has to be transferred with large left margins, these can be divided into a flat margin, designated LR in Fig. 33, and a different letter start margin LB. The flat margin then only needs to be transferred once and the LB margin is then transferred each time. Such edge coding can be initiated manually or determined automatically via a microprocessor.

Claims (9)

1. The method for gray-tone coding and transmission for faxes, characterized in that the pixels are tapped, quantized and coded, if necessary with intermediate storage, are transmitted to the receiver; the receiver provides means which directly encode the pixels, or indirectly after decoding the Convert coded pixels into more or less dense patterns of white and black pixels using the dither printing process. 2. Method for coding and transmission of code words according to claim 1, characterized in that the same code words in a sequence (e.g. lines or blocks of the same color) coded and transmitted in the manner are encrypted by following or before the code word in the sequence the number of sequences of the codewords is provided, the identification of the same is done by saving and comparison. 3. A method for coding and transmission of information according to claims 1 and 2, characterized in that a code with predetermined redundancy is formed ( Fig. 30), so that parts of the same code words also arise in the sequence ( Fig. 30, row 4 , 5), which are transmitted in the respective unit (e.g. line) in such a way that the number of sequences is encoded before or after the partial code word. 4. A method for coding and transmission of information according to claims 1 and 2, characterized in that the quantized values of information of a predetermined section (z. B. line, block) is stored, that the distance of the levels of all values of the respective further Section to each other is determined ( Fig. 31, pixel 7 to pixel 1 = 10 levels) that a reference level is further determined ( Fig. 32, 4, Fig. 31, 8) or z. The smallest or largest level value occurring in the section) and that the reference level and the intended code are transmitted to the receiver which is used for the transmission. 5. A method for coding and transmission of information according to the claims 1 to 4, characterized in that a digital amplitude / phase code with reference phase position and leading and lagging phase positions is provided by the phase stages in conjunction with amplitude stages are presented in the form of periods, with a change in Phase position takes place by reducing or increasing the period duration, the respective phase position is retained if the following Periods have the size of the reference period.   6. Circuit arrangement for generating an amplitude / phase modulation, according to claim 5, characterized in that a timing element is provided with which the period durations are determined ( Fig. 6, Z), the change in the period duration corresponding to the change in the phase position, is still an electronic relay is provided which is controlled by the timer, a coder is arranged so that it defines the period durations once on the timer and directly via the electronic relay the amplitudes of the period durations in accordance with the code. 7. A method for transmitting coded information according to claims 1 to 5, characterized in that the information is distributed over 2 sequences ( Fig. 15) and modulated, added and transmitted on 2 carriers phase-shifted by 90 °, preferably with the coded information such a DC voltage is assigned that the useful values are only in the positive or negative range above the interference level. 8. Image coding method according to claim 1, characterized in that the gray tones are coded and transmitted analogously in such a way that the PAM taps are converted into staircase signals or square-wave pulses and converted to a coding alternating current with the aid of filters, the characteristic states being determined by the Amplitudes of the half-waves or periods are shown, the PAM taps, in particular unipolar, are provided with such a direct current bias ( FIG. 15) that the useful signals in the encoding alternating current are above the interference level, the half-waves or periods can also be two by 90 ° phase-shifted coding alternating currents are distributed, which are then added for the transmission. 9. Image coding method according to claim 1, characterized in that the coding and transmission of the gray tones is carried out analogously by the size of the periods by the amplitudes of the taps (PAM) with the help of an electronic relay ( Fig. 6, ER) in rectangular pulses with a such period duration is converted, which corresponds analogously to the size of the tap voltage, filters are also provided which convert the square-wave pulses into an alternating current.