JP2642219B2 - Image signal editing processor - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial application field] The present invention is applied to an application field such as an image signal editing processing device for editing a screen installed in an information center and transmitted to a G4 facsimile apparatus. Aiming at
^The present invention relates to an image signal editing and processing apparatus for arranging character / graphic information specified by a character / graphic code above pattern information in the 2R encoded image signal format to compose a one-page screen. The combination of the pattern information and the character / graphic information referred to here is intended to combine the pattern information and the character / graphic information on the scanning line of the image signal in the raster format, and to combine the pattern information on the same scanning line. It is not intended to combine text and graphic / graphic information.

[Conventional technology]

Conventionally, when combining the pattern information Qm of characters and graphics code information Pc and M ² R code Kaga signal format specified by the character and graphics codes in one screen, the M ² R code Kaga signal format After temporarily decoding the pattern information Qm into an original image signal (bit pattern format) Qo, the character / graphic code information Pc is used to decode the character / graphic code information.
A composite screen Po = Po + Qo is created by connecting to an image signal Po obtained by generating a graphic pattern, and an M ² R encoded image signal Rm is created by encoding the image signal Ro of the composite screen. Therefore, the pattern information Qm in the M ² R encoded image signal format is
There is a disadvantage that the processing of decoding once and re-encoding is performed, and that a decoding circuit is required in addition to the encoding circuit.

To eliminate these drawbacks, in JP-64-36267, "facsimile transmission device", and means for deleting EOFB code from the pattern information of the M ² R coding format, one scan line by using the horizontal mode code Means are provided for inserting coded data that is all white at a page break, and a method of combining a plurality of pages into one page in the M ² R coded image signal format is disclosed.

FIG. 6 is an explanatory diagram of the processing method described above. First, the EOFB code is deleted from the M ² R encoded data Pm. Next, using the horizontal mode code, M ² R
Connect the encoded data Wm. Next, the other M ² R encoded data Qm is connected. By the above processing, M ² R encoded data
Pm + Wm + Qm can be created.

[Problems to be solved by the invention]

However, in this method, the M ² R encoded data Pm
There is a disadvantage that a decoding circuit (or decoding function) is required to delete the EOFB code. Further, M in the case and M ² R encoded data Wm 1 scanning line to M ² R encoded data Pm deleting the EOFB code connects the M ² R encoded data Wm is all white
^{2 When} connecting the R-encoded data Qm, it is necessary to connect the data at bit boundaries, so the processing time for realizing the connection processing by software becomes longer (the dynamic step of the connection processing is large There are drawbacks. Also, in order to realize the connection processing by hardware, a special codec is required, and there is a disadvantage that a commercially available IC codec cannot be used, or another hardware must be added to the commercially available IC codec. is there.

The present invention makes it possible to use a commercially available IC codec and combine it with software processing by eliminating the above-mentioned drawbacks by making the above-described bit boundary connection processing a partial byte boundary connection processing. Than that
An object of the present invention is to realize synthesis of character / graphic information and pattern information without decoding pattern information.

[Means for solving the problem]

FIG. 1 is a diagram for explaining an image signal connection process according to the present invention. That is, in Japanese Patent Application Laid-Open No. 64-36267, "facsimile transmission apparatus" inserts only one all-white scanning line, whereas in the present invention, a plurality of all-white scanning lines are inserted so that data is at the boundary of a byte. I am trying to do it.

(Operation)

According to the present invention, as shown in FIGS. 1, 4 and 5, when the all white line is added, the V
(0) × N is added to make it a byte boundary. As a result, the connection processing of the M ² R encoded data Qm in FIG. 1 can be realized by the software of the control unit 43.

〔Example〕

FIG. 2 shows an embodiment of a system in which the present invention is applied to a center-end type facsimile communication.
Reference numeral 32 denotes an image signal editing and processing apparatus for realizing the present invention, and reference numeral 33 denotes a G4 facsimile terminal. Next, the operation will be described.

First, the information center 31 determines the character / graphic code information Pc and M ²
Outputs R coded data format of pattern information Qm and (with EOFB code) to an image signal editing device 32, the M ² R encoded data connecting the characters and graphics code information at the top of the pattern information G4 It outputs control information for instructing the facsimile terminal 33 to output.

Next, the image signal editing processor 32 converts the received character / graphic code information Pc into a corresponding character / graphic pattern,
Create a raster format image signal Po. Then, the image signal editing processing device 32 encodes the image signal Po to convert the M ² R encoded image signal P
m, and after adding a plurality of all-white scanning lines as described in FIG. 1, connect the pattern information Qm, and output the M ² R encoded image signal to the G4 facsimile terminal 33. Create Next, the image signal editing processor 32 outputs the M ² R encoded image signal to the G4 facsimile terminal 33.

With the above operation, a screen in which the character / graphic information corresponding portion and the pattern information corresponding portion are combined on one page is output to the G4 facsimile terminal 33. Note that, between the character / graphic information corresponding portion and the pattern information corresponding portion, all the white scanning lines (minimum 2 lines to maximum 9 lines) added in the above processing are inserted as blank lines. .

FIG. 3 shows an embodiment of an image signal editing and processing apparatus used in the present invention. In the figure, 41 is image information input-output terminal for inputting and outputting the M ² R code Kaga signal is input and characters and graphics code information Pc and pattern information Qm combined screen, 42 characters and graphics code information Pc
Control information input terminal for inputting control information for instructing synthesis of the character and pattern information Qm, 43 is a control unit, 44 is a character / graphic pattern generation unit that generates a character / graphic pattern corresponding to the character / graphic information, 45 Is an edit processing unit that edits a character / graphic pattern to create a raster format image signal, and 46 is an encoding processing unit that encodes the image signal in M ² R format.

The encoding processing unit 46 is a commercially available IC codec (for example, HD6
3183), the presence or absence of the EOFB code output can be instructed from the control unit 43. When the encoded image signal buffer (1 byte) in the encoding processing unit 46 becomes full, the control unit 43
Data can be transferred to

 Next, the operation of the image signal editing and processing apparatus will be described.

First, the control unit 43 receives the character / graphic code information Pc and the pattern information Qm from the image information input / output terminal 41 and the control information for instructing the combination of the character / graphic information and the pattern information from the control information input terminal 42. . Next, the control unit 43 is an edit processing unit.
The character / graphic code information Pc is transferred to 45.

The edit processing unit 45 transfers the character / graphic code information Pc to the character / graphic pattern generation unit 44. Character / graphic pattern generator 44
Generates a character / graphic pattern corresponding to the character / graphic code information Pc and transfers it to the edit processing unit 45. The editing processing unit 45 edits the received character / graphic pattern (editing processing such as adding character spacing and line spacing), creates an image signal Po in a raster format, and transfers the image signal Po to the control unit 43. I do.

FIG. 4 and FIG. 5 together show one flowchart, and show the correspondence between the control unit 43 and the encoding processing unit 46. Hereinafter, description will be made with reference to FIGS. 4 and 5.

The control unit 43 receives the image signal Po and the control signal (S1),
(S2) and an initialization instructs the encoding unit 46 (S3), transfers the Eshingo Po (S4), and instructs the M ² R coding without EOFB code (S5). The encoding processing unit 46 performs initialization (S21), receives the image signal Po (S22), performs M ² R encoding (S23), and instructs the control unit 43 every time the internal buffer becomes full (S24). A coded image signal reception instruction signal is transmitted (S25). Then, the M ² R encoded image signal Pm is transmitted (S26). Next, the control unit 43 receives the M ² R encoded image signal Pm every time the encoded image signal reception instruction signal is received from the encoding processing unit 46 (S6) (S7). At this point, the end (one byte end) of the M ² R encoded image signal Pm may remain in the internal buffer of the encoding processing unit 46.

Next, the control unit 43 sends an image signal Wo in which one scanning line is all white to the encoding processing 46 (S8), and instructs M ² R encoding without the EOFB code (S9). The encoding processing unit 46 is an image signal in which one scanning line is all white
Wo is received (S27), and the image signal Wo is M ² R-coded (S2
8), every time the internal buffer becomes full (S29), the control unit 43
(S30). Then, the process proceeds to the illustrated step (S31). Next, the control unit 43 receives the M ² R encoded image signal Wm every time the encoded image signal reception instruction signal is received from the encoding processing unit 46 (S10) (S11). At this point, the end (less than 1 byte) of the M ² R encoded image signal Wm may remain in the internal buffer of the encoding processing unit 46.

Next, the control unit 43 sends an image signal Wo in which one scanning line is all white to the encoding processing unit 46 (S12), and instructs M ² R encoding without EOFB code (S13). The process is repeated until the coded image signal reception instruction signal is received from the unit 46 (provisionally repeated N times) (S14). Next, the encoding processing unit 46
When the scanning line receives the all-white image signal Wo N times (S32), the M ² R encoded image signal V (0) is generated N times (S33), and the internal buffer becomes full (S34). An encoded image signal reception instruction signal is sent to the control unit 43 (S35). (S28), (S3
3) is the process of M ² R encoding of an all-white image signal.
The result obtained in (S28) corresponds to Wm in FIG. 1, and (S33)
Is obtained in the encoded image signal buffer (1 byte) in the encoding processing unit 44 in response to the reception of Wo.
This corresponds to writing (0) = 1. In short, the first Wo
And the result of the second and subsequent Wo receiving processes are different. Then, the process proceeds to step (S36). Next, the control unit 43
Receives the encoded image signal reception instruction signal from the encoding processing unit 46 (S14), and receives the M ² R encoded image signal V (0) × N (S15). At this point, the internal buffer of the encoding processing unit 46 becomes empty. Thereafter, the process ends through steps (S16) and (S17) and steps (S37) and (S38).

Next, the control unit 43 sequentially sends the M ² R encoded image signal Pm + Wm + V (0) × N, the M ² R encoded image signal Qm, and the EOFB code to the image information input / output terminal 41. By the above operation, the M ² R encoded image signal Pm + Wm + V (0) × N + Q of the screen in which the part corresponding to the character / graphic information and the part corresponding to the pattern information are combined on one page
m is output to the image information input / output terminal 41.

The notation “image signal A + B” used in the above description means that the image signal A and the image signal B are continuous.

[Effects of the Invention] As described above, according to the present invention, since a commercially available IC codec can be used, there is an advantage that a special decoding circuit is not required and the hardware configuration is simplified. Also,
The connection processing of the M ² R encoded image signal at the byte boundary can be realized by software, and the pattern information and the character / graphic information can be combined on one page without changing the M ² R encoded image signal. Therefore, for example, when transmitting a message (pattern information), it is possible to add a destination to the upper part of the message and transmit it by specifying the destination information by a character code.

In the screen synthesized according to the present invention, a blank line having a minimum of 2 lines to a maximum of 9 lines is inserted between a portion corresponding to character / graphic information and a portion corresponding to pattern information. However, considering that the scanning line density of the G4 facsimile terminal is about 8 to 16 lines / mm, the length of the blank line is about 1 mm or less, which is negligible.

[Brief description of the drawings]

FIG. 1 is a diagram for explaining a connection processing method of an M ² R encoded image signal in the present invention, FIG. 2 is a diagram showing an embodiment of a system in which the present invention is applied to a center-end type facsimile communication,
FIG. 3 is a diagram showing an embodiment of an image signal editing and processing apparatus according to the present invention, FIGS. 4 and 5 are flowcharts which together form one figure, and FIG. 6 is Japanese Patent Application Laid-Open No. 64-36267. FIG. 4 is a diagram illustrating a connection processing method for an M ² R encoded image signal at a bit boundary disclosed in “Facsimile Transmission Device”. 31 ... Information center, 32 ... Image signal editing processor, 33 ... G4
Facsimile terminal, 41 ... Image information input / output terminal, 42 ... Control information input terminal, 43 ... Control unit, 44 ... Character / graphic pattern generation unit, 45 ... Edit processing unit, 46 ... Encoding processing unit .

Claims (1)

(57) [Claims] And 1. A M ² R coding scheme with redundancy reduction coded pattern information and characters and graphics code characters and graphics information specified in the CCITT recommendation, the function of combining one page screen An image signal editing / processing device using the image information input / output terminal (41), which receives the pattern information and the character / graphic information and outputs an M ² R encoded image signal.
An input terminal (42) for receiving control information for instructing that the character / graphic information is arranged above the pattern information and combined on a one-page screen; and an input terminal (42) for receiving the character / graphic pattern from the character / graphic code. And a character / graphic pattern generating unit (44) for generating a raster-format image signal, and receiving the character / graphic pattern generated by the character / graphic pattern generating unit (44) to determine the character spacing, line spacing, And an editing processing unit (45) for performing an editing process including and, and a control unit (43) sends a raster image signal Po and an M ² R encoding (no EOFB) instruction signal to the encoding processing unit, A first part which waits for input of a reception instruction signal from the encoding processing unit; and a reception instruction signal and an M ² R encoded image signal Pm from the encoding processing unit.
Is received, the input of the next reception instruction signal is awaited,
If the input wait has elapsed for a predetermined time or more, the second part shifts to the third part, and the all-white image signal Wo and the M ² R encoding (no EOFB) instruction signal are encoded. A third part which is transmitted to the processing unit and waits for input of a reception instruction signal from the encoding processing unit; and a reception instruction signal and an M ² R encoded image signal Pm from the encoding processing unit.
Upon reception of the rest and M ² R code Kaga signal Wm, it waits for an input of the next received instruction signal, in the case where the input waiting has passed over a predetermined time period a fourth to move to the fifth portion
And an all-white image signal Wo and an M ² R encoding (without EOFB) instruction signal are sent to the encoding processing unit, and the input of a reception instruction signal from the encoding processing unit is waited for. Upon receipt, the process proceeds to the sixth part. If the input wait has elapsed for a predetermined time or more, the fifth part to be executed from the beginning of the fifth part is executed.
When the reception instruction signal is received from the encoding processing unit, the remaining M ² R encoded image signal Wm and the M ² R encoded image signal V (0) × N are received, and an EOFB code transmission instruction is received. A sixth part to be sent to the encoding processing unit, a seventh part to receive the EOFB code, and an M ² R encoded image signal (Pm + Wm +
V (0) × N + Qm ) and EOFB and a eighth portion of sequentially sending the code, encoding processing unit (46), based on the image signal Po and coded instruction signal received raster format M ² perform R coding, every time the internal buffer is full by M ² R code Kaga signal, received instruction signal and M ² R code Kaga signal P
m to the control unit, and if the internal buffer is not full due to the end of the M ² R coded image signal, a ninth part waiting for input of an all-white image signal Wo; M ² R based on image signal Wo and encoding instruction signal
Performs encoding, when the internal buffer is full by M ² R code Kaga signal, sent to the control unit together with the received instruction signal remaining and M ² R code Kaga signal Wm of the M ² R code Kaga signal Pm and, if the internal buffer is not full by M ² R code Kaga signal, tenth portion and, of all white received image signal Wo and coding instruction signal to be input wait picture signal Wo of the total white Based on M ² R
Encoding is performed, and the M ² R encoded image signal V (0) is written into the remainder of the internal buffer that is not full, and the next all-white image signal Wo and an encoding instruction signal are awaited for input. Writing to the buffer is performed until the internal buffer is full. When the internal buffer is full, the reception instruction signal is sent together with the remainder of the M ² R encoded image signal Wm and the M ² R encoded image signal V (0) × N. After receiving an EOFB code transmission instruction and creating an EOFB code, an EOFB code
A twelfth part for sending an FB code to a control unit, wherein the character / graphic information is arranged above the pattern information to create an M ² R encoded image signal of a combined screen as one page. An image signal editing and processing device, characterized in that: