SU862389A1 - Facsimile device - Google Patents

Description

(54) FAX DEVICE

The invention relates to devices for the facsimile transmission of half-tone images and can be used to register individual zones of optical densities of half-tone images, for example, for cloud cover images. A facsimile device is known comprising a scanning unit and a generator of reference signals optically coupled to the illuminator, a synchronizer whose first output is connected to the input of the GO scanning unit. However, the known facsimile device does not provide a distinction between halftone gradations of the image. The aim of the invention is to provide a halftone gradation of the image. To do this, a resistor divider consisting of N pairs of resistors, the channel of which is connected to the midpoint of each pair is connected to a facsimile device containing a scanner unit and a generator of reference signals optically connected to the illuminator. information processing system, containing a series-connected detection unit zero, a trigger and a memory unit, each of the N outputs of the reference signal generator being connected to one of the terminals. divider resistors, another input of each divider resistor pair is connected to the output of the scanning unit, the second synchronizer output is connected to the reset input of all triggers of N information processing channels .. The third synchronizer output is connected to the enabling input of all triggers of N information processing channels, and the outputs of all the storage blocks and the fourth output of the synchronizer are connected to the redundancy reduction unit. 38 The drawing shows the structural electrical circuit of the proposed device, the Fax device, the device contains an illuminator 1, optically connected with a generator of reference sigtals 2 and a scanning unit 3, a divider 4 is a state and e N pairs of resistors 5, .6 (5-1 .. 5 -N, 6-1 ... 6-N), to the midpoint of each pair of which the information processing channel 7 is connected, the detection unit 8 connected in series, the trigger 9 and the storage unit 0, the redundancy reduction unit P and the synchronizer 12 The fax machine works as follows m. A part of the luminous flux from the illuminate l 1 excites a generator of signaling signals 2, N is opposed to the voltage. Another part of the light flux, reflected from the original halftone image, enters the scanning unit 3, where it is converted into an electric signal. In the initial state, for example, when reading the white floor of the original, the first output voltage of the generator of the reference signals 2 and the scan of the hand block 3 are set to the same gun. As a result, at the outputs of the generator of the reference signals 2, N reference voltages are formed, corresponding to the nature of the change in optical density of the halftone wedge. These signals and signals proportional to the optical density of the image received from the scanning unit 3 through the respective pairs of resistors 5-6 of the divider are fed to the inputs of the zero-detection block B. If the voltage level of the image signal is equal to one of the voltage levels of the signal generator 2 , the voltage drops across the corresponding resistors 5 and 6 will become the same and, causing a voltage of zero at the point of their connection. This voltage will cause the output at the output of the corresponding detection unit to zero 8 logical zero, while all other detection units zero that received a voltage at the outputs that is not equal to nugav will have a logic level 1 at the outputs. Signals from the outputs of each of the blocks The zero detection coil 8 arrives at the synchronization input 1 of the corresponding trigger 9, controlled by synchronizer 12 via second inputs, for example, enabling, and third inputs, for example, reset. At the input from synchronizer 12, a logical 1 signal is received, which prepares for the operation N ace of triggers 9, but only one of them, to the input of which it receives a VO logical A logic. O. After triggering, none of the triggers it returns to its original the state of the logical O signal, which is fed to the reset inputs of all the triggers from synchronizer 12 before the arrival of information from the next raster element. In addition, the signal from the synchronizer enters the scanning unit 3 and synchronizes its operation, i.e. the appearance of the image signal of the raster element synchronously with the preparation of triggers 9 for operation. From the output of each trigger signal, the signals are fed to the inputs of the respective storage units 10, each of which contains an n-bit code corresponding to the 5th semitone of the image, which is determined by. the formula: where N is the number of grayscale gradations; about - the number of bits in each semitone. The trigger signal 9 triggers the corresponding storage unit 10, KOT01NLE1 sets the n-bit code in parallel to the whole redundancy reduction block 1I, which eliminates the information redundancy in the digital signal, representing a gray scale image, and sends the digital signal to the communication channel in the serial the form. The operation of this block is controlled by synchronizer 12. Information can be transmitted to the communication channel directly without removing redundancy. Then redundancy block 11 will be, with parallel input and sequential code output. In addition, from the output of each of the flip-flops 9, the signals are fed to the inputs of the recorders for simultaneous recording of individual zones of the transmitted half-tone image, the optical density of each of which corresponds to one half-tone gradation. In the proposed facsimile device, halftone image gradations are distinguished.

Claims (1)

Claim A facsimile device containing a scanning unit and a reference signal generator, optically coupled to a · 5 illuminator, a synchronizer, the first output of which is connected to the input of the scanning unit, with the exception of the fact that, in order to ensure differentiation grayscale image gradations, a resistor divider is introduced, consisting of N pairs of resistors, to the midpoint of each pair of which is connected an information processing channel containing serially connected ^ zero detection unit, a trigger and a storage unit, each of N the outputs of the reference signal generator are connected to one of the outputs of the corresponding pair of divider resistors, the other output of each pair of divider resistors is connected to the output of the scanning unit, the second synchronizer output connected to the reset input of all triggers of N information processing channels, the third synchronizer output connected to the enable input all triggers of N channels of information processing, and the outputs of all storage units and the fourth output of the synchronizer are connected to the redundancy reduction unit.