JP2004146933A - Image data transmitter, image data receiver, and image data transceiver - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image data transmitter capable of encrypting image data in parallel with execution of coding processing without the need for particular encryption processing and to provide an image data receiver and an image data transceiver. <P>SOLUTION: A 'value of a coding interval' used in a process of an arithmetic coding processing by a QM-Coder adopting the JBIG coding system is made variable. Only a receiver capable of recognizing a revised 'value of coding interval' can decode data as a correct image. Thus, the image data are concealed and the concealment of the image data is executed in parallel with execution of the coding processing. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an image data transmitting apparatus represented by a facsimile apparatus, an image data receiving apparatus for receiving image data transmitted by the image data transmitting apparatus, and an image data transmitting / receiving apparatus having the functions of these apparatuses. In particular, the present invention relates to improvements in techniques for encoding and concealing image data.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, in a facsimile apparatus, when image data is transmitted, first, image data of a document read by a scanner is converted by a coding / decoding control unit into a modified Huffman (MH) coding method, a modified relative element addressing (MR). The compression coding is performed by a coding method or a standard coding method for binary facsimile such as an MMR (Modified MR) coding method. Thereafter, the coded image data is temporarily stored in an image memory and output to a line, thereby transmitting the coded image data to a destination (destination) facsimile machine.
[0003]
Further, when the facsimile apparatus receives the encoded image data, it temporarily stores it in the image memory. After that, the encoded image data is decoded into the original image data by the encoding / decoding control unit, and the printing unit records and outputs it on recording paper.
[0004]
By the way, in this type of facsimile apparatus, there is a demand for an encoding method capable of improving the image compression ratio in order to handle a large amount of image data, thereby shortening the communication time and reducing the communication cost. I was
[0005]
To meet the demand, for example, the JBIG (Joint Bi-level Image Experts Group) system, which is standardized by the International Telecommunications Unit (ITU-T) (ITU Recommendation T.82), is known. ing.
[0006]
In the JBIG method, as disclosed in Patent Literature 1 below, an image is decomposed into binary bit planes and encoded using a binary arithmetic encoding method called QM-coder. is there. The QM-coder arithmetic coding method performs coding and decoding by repeating context generation, estimation of symbol occurrence probability information, and arithmetic coding operation for each symbol. It can be carried out.
[0007]
Hereinafter, the QM-coder arithmetic coding scheme will be described. FIG. 10 is a block diagram illustrating a schematic configuration of the QM-coder. As shown in this figure, the QM-coder includes a context generation unit 200, a context table (RAM) 210, a probability estimation unit 220, and an arithmetic encoder 230, and operates as follows.
[0008]
First, the context generation unit 200 detects 1024 states formed by the ten pixels around the coded pixel. Each state is called a context, and the predicted value MPS of the dominant symbol and the state number of the probability estimating unit 220 are read from the context table 210 for each context, and output to the probability estimating unit 220. The probability estimating unit 220 outputs the region width Qe to the arithmetic coder 230 from these pieces of information. Arithmetic encoder 230 performs an arithmetic encoding operation from the encoded symbol value, the predicted value MPS of the superior symbol, and the region width Qe corresponding to the generation probability of the inferior symbol.
[0009]
Next, a specific arithmetic coding operation will be described with reference to FIG. In this arithmetic coding operation, the initial value of the A register is set to “1” and the initial value of the C register is set to “0”, and the number line in the range of “0” to “1” is set to the value of the superior symbol (MPS). It is divided into the area width and the area width of the recessive symbol (LPS). Here, the value given to the A register is a value that determines the size of the coding interval, and the value given to the C register is a value that determines the lower limit value of the coding interval. In the QM-coder, the LPS width is assigned to the upper side of the number line and the MPS width is assigned to the lower side, and the width obtained by adding these two area widths is called an agent.
[0010]
FIG. 11 illustrates four pixels (hereinafter, first to fourth pixels) that are “black, white, black, and white” when “1010” (“0” is a white pixel and “1” is a black pixel). FIG. 10 is a diagram for explaining the principle of encoding processing for a configured image area).
[0011]
First, in accordance with the probability estimated value LSZ (0) estimated and calculated by the probability estimating unit 220, the number line of initial values 0 to 1 (the area of width A (0) in the figure) is changed to the area of the dominant symbol (MPS). The width (the width of “A (0) -A (1)” in the figure) and the area width of the recessive symbol (LPS) (the width of “A (1)” in the figure) are divided.
[0012]
When the first pixel is black, that is, “1”, the probability estimating unit 220 is applied to the area width of “1” (the width of “A (1)” in the drawing) in the same manner as described above. In accordance with the probability estimation value LSZ (1) estimated and calculated in (1), the number line having the width indicated by “A (1)” in the figure is changed to the area width of the dominant symbol (MPS) (“A (2)” in the figure). Width) and the area width of the recessive symbol (LPS) (the width of “A (1) -A (2)” in the figure).
[0013]
When the second pixel is white, that is, “0”, the probability estimating unit 220 is applied to the area width of “0” (the width of “A (2)” in the drawing) in the same manner as described above. According to the probability estimation value LSZ (2) estimated and calculated in the above, the number line having the width indicated by “A (2)” in the figure is drawn to the area width of the dominant symbol (MPS) (“A (2) −A in the figure”). (3) ”and the area width of the recessive symbol (LPS) (the width of“ A (3) ”in the figure).
[0014]
Here, when the third pixel is black, that is, “1”, the probability estimating unit performs the same processing on the area width of “1” (the width of “A (3)” in the drawing) as described above. According to the probability estimation value LSZ (3) estimated and calculated at 220, the number line having the width indicated by “A (3)” in the figure is divided into the area width of the superior symbol (MPS) and the area width of the recessive symbol (LPS). And divided into
[0015]
By dividing the region width in this way, the region width is narrowed down according to the black and white binary array pattern, and finally the region converges near the point indicated by the broken line A in the figure (for example, FIG. Converges to around 0.75 on the number line). By extracting one point (for example, 0.75) in the convergence area as encoded data, encoded data obtained by compressing image data of four pixels composed of “black, white, black, white” is obtained. It is obtained.
[0016]
By performing such a process on the entire surface of the original, it is possible to encode the original image data at a high compression rate.
[0017]
When the compressed (encoded) image data has high confidentiality, generally, the image data is concealed. Patent Document 2 listed below discloses concealment of the image data and arithmetic coding of the image data by the QM-coder. Specifically, a method is disclosed in which anonymous image data is created based on predetermined anonymous data, and the anonymous image data and anonymous data are individually encoded and transmitted to a receiving device. I have.
[0018]
[Patent Document 1]
JP 2001-57638 A
[Patent Document 2]
JP 2000-244748 A
[0019]
[Problems to be solved by the invention]
However, in the concealment method disclosed in Patent Document 2, the image data before concealment is transmitted in order to secure the confidentiality of the image data with respect to the transmission of the image data encoded by the ordinary JBIG method. It must be an irregular image that cannot be guessed.
[0020]
For this reason, the compression ratio of the JBIG system is reduced, and the communication cost and the communication time are increased. Further, in order to create the concealed image data separately from the encoding process, the arithmetic processing of the image data and the concealment data is required, and there is a disadvantage that a long processing time is required.
[0021]
The present invention has been made in view of such a point, and an object of the present invention is to perform concealment of image data along with execution of encoding processing without performing special concealment processing. It is an object of the present invention to provide an image data transmitting apparatus, an image data receiving apparatus, and an image data transmitting / receiving apparatus that can perform the processing.
[0022]
[Means for Solving the Problems]
-Summary of the invention-
In order to achieve the above object, the present invention makes the parameters of the algorithm used in the process of the arithmetic coding process of the JBIG system variable, and changing this parameter exerts the function of concealing image data. I have to. This parameter is a "coding interval value" set in the A register.
[0023]
-Solution-
Specifically, arithmetic coding means for performing arithmetic coding of the JBIG method on the image data and transmission means for transmitting transmission data including the arithmetically coded image data to the image data receiving apparatus are provided. It is assumed that the image data transmitting apparatus is provided. The image data transmitting apparatus is provided with an interval changing unit that can change a value of a coding interval used in the arithmetic coding of the JBIG system in the arithmetic coding unit.
[0024]
The specific means for specifying the algorithm used for the arithmetic coding of the JBIG method is as follows. That is, the image processing apparatus includes arithmetic coding means for performing arithmetic coding on image data by QM-coder and transmission means for transmitting transmission data including the arithmetically coded image data to the image data receiving apparatus. It is assumed that an image data transmission device is used. This image data transmitting apparatus is provided with an interval changing means for changing a value of a coding interval used at the time of arithmetic coding by QM-coder in the arithmetic coding means.
[0025]
Heretofore, the initial value of the A register storing the size of the encoding interval has been defined as 1 (decimal). For this reason, the decoding side (receiving device) performs decoding on the assumption that the initial value of the size of the encoding interval is “1”. On the other hand, in the present solution, an arbitrary value other than “1” can be set as the value of the encoding interval (that is, the initial value of the A register), and the value of the changed encoding interval is set to Only a known receiving device can decode data as a correct image. In other words, in a receiving apparatus that cannot know the value of the changed encoding interval, it is impossible to accurately decode the image data, so that concealment can be achieved.
[0026]
Thus, in the present solution, if the algorithm of the related art (arithmetic coding by QM-coder) is executed, the concealment of the image data can be performed as it is. That is, the image data can be concealed in parallel with the execution of the encoding process without performing any special concealment processing. Furthermore, since the steps of compression (encoding) and concealment can be performed in a single process, the concealed image data can be converted while the processing time and compression ratio are almost unchanged as compared with the case of only normal compression processing. Obtainable. In particular, when a random value is used as the value of the encoding interval, confidentiality can be further improved.
[0027]
In addition, the following configuration is given as a configuration for giving information on the value of the changed encoding interval to the receiving device that receives the encoded and concealed image data. In other words, the configuration is such that there is provided a notifying unit that includes, in the transmission data, notification information for notifying the image data receiving apparatus of the value of the encoding interval changed by the interval changing unit.
[0028]
According to this specific matter, the value of the encoding interval can be notified to the receiving device together with the transmission data, and the decoding process in the receiving device can be easily performed. In this case, the receiving apparatus needs to have a function of recognizing the changed value of the encoding interval and executing decoding based on the value. That is, in a receiving apparatus that does not have this function, accurate decoding of image data is impossible, and concealment can be achieved.
[0029]
The following configurations are listed as means for further concealment. That is, when notifying the image data receiving device of the value of the encoding interval changed by the interval changing unit, the image data receiving apparatus is provided with an encrypting unit for encrypting the value of the encoding interval.
[0030]
According to this, it is possible to obtain extremely high confidentiality due to a synergistic effect between the encryption of the value of the encoding interval and the concealment of the image data due to the change of the value of the encoding interval. Also, since only information having a relatively small data amount, such as an encoding interval value, is encrypted, the processing time and the total communication data amount are not increased, so that confidentiality can be improved and processing time can be lengthened. Can be achieved at the same time.
[0031]
In addition, as the form of the notification information given in the transmission data by the above-mentioned notification means for notifying the receiving apparatus of the changed value of the encoding interval, the following is listed.
[0032]
First, the value of the encoding interval changed by the interval changing means is notified to the image data receiving apparatus by a comment marker in the transmission data.
[0033]
Also, the value of the encoding interval changed by the changing means is stored as electronic mail information.
[0034]
Further, the value of the encoding interval changed by the changing means is notified to the image data receiving apparatus by using a facsimile communication procedure signal.
[0035]
By these means, even if the receiving side does not know the value of the encoding interval in advance, the value of the encoding interval can be acquired at the same time as the data reception, and the decoding can be easily performed. In the case of using the comment marker in the transmission data, the value of the encoding interval is stored as the comment of the comment marker in the JBIG code data generated by using the encoding / decoding capability, and is notified to the receiving side. Will do. Since the concealment interval value, which is the data for concealment, is 2-byte data and the comment marker is 6-byte data, the increase in the communication cost is very small even if it is notified to the receiving side.
[0036]
Further, an image data receiving device that receives encoded image data transmitted from an image data transmitting device according to any one of the above-described solving means is also within the scope of the technical idea of the present invention. In other words, the image data receiving apparatus includes an arithmetic decoding unit that decodes the received encoded image data based on the value of the encoding interval changed by the interval changing unit.
[0037]
Further, there is also provided an image data transmitting / receiving apparatus having both the arithmetic coding function and the transmitting function of the image data transmitting apparatus according to any one of the above-mentioned solving means and the receiving function and the arithmetic decoding function of the image data receiving apparatus. This is a category of the technical idea of the present invention.
[0038]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. In this embodiment, the present invention is applied to a facsimile / e-mail device (image data transmitting / receiving device) having both a function as an image data transmitting device and a function as an image data receiving device. A case where a LAN (Local Area Network) is constructed by the device will be described.
[0039]
-Explanation of network configuration-
FIG. 1 shows a schematic configuration of a network constructed by a facsimile / e-mail device 11 according to the present embodiment. As shown in FIG. 1, in this network, each facsimile / e-mail device 11, 11 is connected to a mail server 50, 50, respectively, to construct an individual LAN, and each mail server 50, 50 is connected to the Internet. By being connected, various data such as image data and e-mail can be transmitted and received between the LANs, that is, between the facsimile / e-mail devices 11 and 11. Each of the facsimile / e-mail devices 11, 11 is also connected to a telephone line (general public telephone line), and can transmit and receive facsimile image data.
[0040]
-Description of the configuration of the facsimile / e-mail device 11-
FIG. 2 is a block diagram showing an electrical configuration of the facsimile / e-mail device 11 according to the present embodiment. As shown in FIG. 2, the facsimile / e-mail device 11 according to the present invention transmits and receives data via a network according to a predetermined transmission setting. Since each facsimile / e-mail device 11 in FIG. 1 has the same configuration, only one facsimile / e-mail device 11 will be described here as a representative.
[0041]
The facsimile / e-mail device 11 has a function as a printer / copy for printing data (image data) on a recording medium, a function as a normal facsimile (FAX) using a telephone line, and a network such as the Internet. (E-mail / File Transfer Protocol (FTP) device) for transmitting and receiving electronic mail (E-mail) and transmitting and receiving files to and from a server, and an Internet facsimile device.
[0042]
The facsimile / e-mail device 11 includes a main control unit 12, a panel control unit 13, a control memory 14, an image buffer 15, a control buffer 16, an image storage unit 17, an e-mail creation unit 18, a reading unit 19, and a recording unit. 1 includes a unit 20, an encoding / decoding control unit 21, a LAN (Local Area Network) control unit 22, a modem 23, and a network control unit (NCU: Network Control Unit) 24. Hereinafter, each unit will be described.
[0043]
The main control unit 12 includes a CPU (Central Processing Unit) and the like, and controls the entire facsimile / e-mail device 11 in an integrated manner. The panel control unit 13 is for instructing reading of a document, input of a destination, and the like, and details will be described later.
[0044]
The control memory 14 includes a nonvolatile memory such as a ROM, a volatile memory backed up, and the like, and various control programs such as a JBIG communication control processing program and other party information (telephone number of transmission destination, abbreviated number, etc.). ) Are stored, as well as system data and various data necessary to execute these control programs. The image buffer 15 is composed of a RAM or the like, and is used for temporary storage when compressing and expanding image data to be transmitted and received. The control buffer 16 is composed of a RAM or the like, and stores data necessary for operating the control program. The image storage unit 17 stores coded image data, and also stores data read from a reading unit 19 described later, received data, decoded data, and the like.
[0045]
The e-mail creating unit 18 adds header information to the encoded image data and converts the image data into an e-mail format. The reading unit 19 reads a document at a predetermined resolution by a scanner using a photoelectric conversion element (CCD; Charge Coupled Device) as a document reading unit. Then, as a result of the reading, dot image data is output. The recording unit 20 includes an electrophotographic printer device, and makes a hard copy (printout) of data such as a document image received by communication and a document image read by the reading unit 19. Further, the present invention may be configured as a thermal recording apparatus using a thermal element.
[0046]
The encoding / decoding control unit 21 performs encoding of the data of the read original image and decoding when receiving the image data. That is, the encoding / decoding control unit 21 encodes and compresses the data of the original image read by the reading unit 19 by the arithmetic encoding operation in the QM-coder described with reference to FIG. The received received image data is decoded into the original data. The encoding / decoding control unit 21 uses an encoding method of a JBIG (Joint Bi-level Image Experts Group) method. The encoding and decoding of image data in the encoding / decoding control unit 21 will be described later.
[0047]
The LAN control unit 22 is for connecting to a LAN (Local Area Network) so as to perform transmission / reception communication of electronic mail via the Internet and communication of Internet facsimile. The modem 23 is composed of a facsimile modem that modulates a transmission signal of G3 communication into a form suitable for transmission on a line and demodulates a modulation signal sent from the line. This modem 23 is connected to a public telephone line via a network control unit 24. The network control unit 24 is hardware for performing line control operations for closing and opening a line with an analog public telephone network (PSTN), and connects the modem 23 to the public telephone network as necessary. That is, the network control unit 24 performs transmission / reception of image data and transmission / reception of control signals according to the G3 communication protocol, and also performs automatic call origination / reception processing.
[0048]
As features of the facsimile / e-mail device 11, an interval changing unit 26 as interval changing means, a notifying unit 27 as notifying means, and an encryption creating unit 25 as encryption means are provided. Hereinafter, each means will be described.
[0049]
The interval changing unit 26 is capable of changing the value of the encoding interval used at the time of the arithmetic encoding operation in the QM-coder described with reference to FIG. Until now, the initial value of the A register storing the size of the encoding interval has been defined as “1 (decimal)”. However, the interval changing unit 26 according to the present embodiment uses the value of this encoding interval. A receiving device which can randomly set an arbitrary value (for example, a value such as 0.8 or 0.5) other than "1" as an (initial value of the A register) and can know the value of the changed encoding interval Only the other party's facsimile / e-mail device 11 can decode the image data as a correct image.
[0050]
The notifying unit 27 includes, in the transmission data, notification information for notifying the facsimile / e-mail device 11 (image data receiving device) of the other party of the value of the encoding interval changed by the interval changing unit 26. Means. Thereby, the value of the encoding interval is notified to the other party's facsimile / e-mail device 11 together with the transmission data, so that the decoding process in the other party's facsimile / e-mail device 11 can be easily executed. .
[0051]
Specifically, the value of the encoding interval can be notified to the facsimile / e-mail apparatus 11 of the other party by the following three methods according to the transmission mode of the image data.
[0052]
First, as a first method, when image data is transmitted by Internet facsimile or electronic mail, the value of the encoded interval changed by the interval changing unit 26 is changed by the comment marker in the transmission data to the other party. The facsimile / e-mail device 11 is notified.
[0053]
Here, the comment marker will be described. FIG. 3 is a diagram showing a data structure transmitted by JBIG (a data structure in the case of Internet facsimile or electronic mail). This data is composed of a binary image header (BIH) containing various compression parameters and compressed binary image data (BID), and a comment marker can be inserted into the BID. Then, information on the value of the encoding interval is written in the private comment of this comment marker segment. The private comment is an area where the data length is variable and arbitrary data can be written.
[0054]
The second method is a case in which image data is transmitted by e-mail, in which the value of the encoded interval changed by the interval change unit 26 is stored as e-mail information. FIG. 4 shows a case where the value of the encoding interval (“0.8” in the example shown in FIG. 4) is stored in the header information of the electronic mail. FIG. 5 shows a case where the value of the encoding interval is stored in the body of the electronic mail.
[0055]
Further, as a third technique, when image data is transmitted by a normal facsimile using a public telephone line, the value of the coded interval changed by the interval changing unit 26 is used as a facsimile communication procedure signal (voice signal). ) To notify the facsimile / e-mail device 11 of the other party.
[0056]
According to these methods, in any communication mode, the value of the encoding interval can be acquired at the same time as the data reception even if the receiving side does not know the value of the encoding interval in advance, and the decoding can be easily performed. In the case of using the comment marker in the transmission data, the value of the encoding interval is stored as the comment of the comment marker in the JBIG code data generated by using the encoding / decoding capability, and is notified to the receiving side. However, since the concealment interval value, which is data for concealment, is 2-byte data and the comment marker is 6-byte data, the increase in communication cost is very small even if notification is made to the receiving side.
[0057]
The encryption creating unit 25 encrypts the value of the encoding interval itself when notifying the value of the encoding interval changed by the interval changing unit 26 to the facsimile / e-mail device 11 of the other party. This makes it possible to obtain extremely high confidentiality due to a synergistic effect between the encryption of the value of the encoding interval and the concealment of image data due to the change of the value of the encoding interval. Also, since only information having a relatively small data amount, such as an encoded interval value, is encrypted, it is possible to improve the confidentiality and avoid a prolonged processing time without increasing the processing time and the overall communication amount. It is also possible to achieve both. The encryption technology used in the encryption creating unit 25 includes well-known PGP (Pretty Good Privacy), DES (Data Encryption Standard), and the like.
[0058]
-Description of transmission operation of facsimile / e-mail device 11-
Next, an operation when the facsimile / e-mail device 11 functions as a facsimile device and transmits encoded image data will be described with reference to the flowchart of FIG.
[0059]
First, a document is set on a document table (not shown) (step ST1), and the destination (facsimile / facsimile number of the electronic mail device 11) and transmission conditions (necessity of encoding and concealment) are controlled by the panel controller 13. Is input (step ST2). When an instruction to start transmission is given by operating the transmission start button (step ST3), the encoding / decoding control unit 21 sets the value of the encoding interval. This value is a value other than “1” and is set at random (for example, “0.8”).
[0060]
Thereafter, the reading section 19 starts the reading operation of the originals taken out one by one from the original table (step ST5). Accordingly, the encoding / decoding control unit 21 arithmetically encodes the data of the document image read by the reading unit 19 (step ST6). The details of the image data encoding process performed at this time will be described later.
[0061]
Transmission data is created based on the above-described setting of the encoding interval value and the arithmetic encoding of the document image data (step ST7).
[0062]
In creating this transmission data, it is determined in step ST8 whether or not the value of the encoding interval itself needs to be encrypted. If so, the encryption creating unit 25 encrypts the value of the encoding interval. (Step ST9) Then, the process proceeds to Step ST10. That is, for image data with extremely high airtightness, the value of the encoding interval itself is also encrypted to improve confidentiality. On the other hand, if it is determined that encryption is not necessary, the process proceeds to step ST10 without encrypting the value of the encoding interval.
[0063]
The transmission data created in this way is transmitted to the facsimile / e-mail device 11 of the other party in step ST10, and the transmission operation is completed (step ST11).
[0064]
Next, an operation when the facsimile / e-mail device 11 functions as an Internet facsimile device or an e-mail device and transmits image data will be described. In this case, after the facsimile document data is encoded by the image data encoding process described later, the encoded facsimile document data is added with header information in the e-mail creating unit 18 and converted into an e-mail format. .
[0065]
That is, the present apparatus 11 adds the facsimile document data to the e-mail address to which the facsimile document data is transmitted and converts the data into an e-mail. Then, it is connected to an Internet provider (corresponding to the mail server on the transmitting side in FIG. 1) through a public telephone line or the like, and is connected to the Internet via its host, or is directly connected to the Internet, and is connected to a mail server on the network. (Equivalent to the mail server on the receiving side in FIG. 1).
[0066]
Then, the facsimile / e-mail device 11 on the transmission side and the facsimile / e-mail device 11 on the reception side are both connected to the Internet, so that transmission / reception of e-mail can be performed.
[0067]
In this case, as shown in FIGS. 4 and 5, the value of the encoding interval is stored in the header information of the email or in the body of the email. Alternatively, as shown in FIG. 3, the value of the encoding interval is stored in the comment marker.
[0068]
-Description of reception operation of facsimile / e-mail device 11-
Next, a receiving operation when the facsimile / e-mail device 11 receives image data will be described with reference to a flowchart of FIG.
[0069]
First, when it is determined that image data has been received (YES in step ST21), in step ST22, it is determined whether or not the encoding interval value has been notified, that is, information on the encoding interval value is included in the transmission data. It is determined whether or not it is included.
[0070]
If this determination is YES, information on the encoded interval value is extracted and the value is analyzed (step ST23). Then, it is determined whether or not the value of the encoding interval itself has been encrypted (encrypted by the encryption creating unit 25) (step ST24). The conversion process is executed to perform plain text (step ST25), and the process proceeds to step ST26.
[0071]
On the other hand, if the encoded interval value has not been notified (NO in step ST22), the process proceeds to step ST26 without executing the encoding interval value analysis operation. If the value of the encoding interval is not encrypted (NO in step ST24), the process proceeds to step ST26 without executing the above-described plain text processing.
[0072]
Then, in step ST26, a printing (printing) operation is started to output the received image data in the recording unit 20. Along with the start of the printing operation, in step ST27, arithmetic decoding of the received image data is executed, and when the arithmetic decoding of all the image data and the printing operation are completed, the receiving operation is completed.
[0073]
At this time, if the coded interval value has been notified (if determined to be YES in step ST22), the image is calculated using the coded interval value (for example, “0.8”) analyzed in step ST23. Perform arithmetic decoding of data. On the other hand, when the encoding interval value has not been notified (when determined to be NO in step ST22), the encoding interval value is set to “1” as in the related art, and arithmetic decoding of image data is executed.
[0074]
-Image data encoding process-
Next, the principle of the image data encoding process (the arithmetic encoding operation executed in step ST6) executed in the encoding / decoding control unit 21 of the facsimile / e-mail device 11 according to the present embodiment will be described with reference to FIG. Will be explained. Here, a case where “0.8” is set as the value of the encoding interval (initial value of the A register) will be described. It should be noted that even when a value of the encoding interval other than “0.8” is set, the image data encoding process is executed according to the same principle.
[0075]
In the arithmetic coding operation shown in FIG. 8, the initial value of the A register is set to “0.8”, the initial value of the C register is set to “0”, and the number line in the range of “0” to “0.8” is set. Is divided into a region width of a dominant symbol (MPS) and a region width of a recessive symbol (LPS). In the QM-coder, the LPS width is allocated above the number line, and the MPS width is allocated below the number line.
[0076]
FIG. 8 illustrates the principle of the encoding process for “1010” (that is, an image area including four pixels “black, white, black, and white” (hereinafter, first to fourth pixels)). FIG.
[0077]
First, in accordance with the estimated and calculated probability estimation value LSZ (0), a number line with an initial value of 0 to 0.8 (the area of width A (0) in the figure) is changed to the area width of the dominant symbol (MPS) (in the figure). (A (0) -A (1))) and the area width of the recessive symbol (LPS) (the width of “A (1)” in the figure).
[0078]
When the first pixel is black, that is, “1”, the probability estimation value LSZ (1) estimated and calculated for the region width of “1” (the width of “A (1)” in the drawing) ), The number line having the width indicated by “A (1)” in the figure is divided into the area width of the dominant symbol (MPS) (the width of “A (2)” in the figure) and the area of the recessive symbol (LPS). Width (width of “A (1) -A (2)” in the figure).
[0079]
When the second pixel is white, that is, “0”, the estimated probability value LSZ (LSZ () is calculated for the region width of “0” (the width of “A (2)” in the drawing). According to 2), the number line having the width indicated by “A (2)” in the figure is divided into the area width of the dominant symbol (MPS) (the width of “A (2) −A (3)” in the figure) and the inferiority. Symbol (LPS) area width (width of “A (3)” in the figure).
[0080]
Here, when the third pixel is black, that is, “1”, the estimated probability value LSZ (LSZ () is estimated for the region width of “1” (the width of “A (3)” in the drawing). According to 3), the number line of the width indicated by “A (3)” in the figure is divided into the area width of the superior symbol (MPS) and the area width of the recessive symbol (LPS).
[0081]
By dividing the region width in this way, the region width is narrowed down according to the black and white binary array pattern, and finally the region converges near the point indicated by the broken line A in the figure (for example, FIG. If so, it converges around 0.58 on the number line). By extracting one point (for example, 0.58) in the convergence area as encoded data, encoded data obtained by compressing image data of four pixels composed of “black, white, black, white” is obtained. It is obtained. In other words, by setting “0.8” as the value of the encoding interval, encoded data “0.58” is obtained. In the conventional case, when the same image is encoded, the value of the encoding interval is “1”, and thus the encoded data “0.75” is obtained (see FIG. 11). .
[0082]
-Image data decoding process-
Next, the state of decoding by the encoded data obtained by encoding as described above will be described.
[0083]
The image data receiving device (the facsimile / e-mail device 11 in the present embodiment) which can know the value of the changed encoding interval receives the encoded data and decodes it. An image data receiving device (conventional facsimile / e-mail device) that cannot be known, that is, a case where the value of the encoding interval is set to “1” and decoding of the encoded image data will be described below in comparison.
[0084]
First, when the image data receiving device that can know the changed value of the encoded interval receives and decodes the encoded data, the value of the encoded interval is set to “0.8”, and the encoded data “ 0.58 ”(arithmetic decoding in step ST27). That is, it is recognized that the image is an image in which the area is converged near the point indicated by the broken line A in FIG. As a result, it is correctly decoded that the pixel data is "1010", that is, the image data of four pixels "black, white, black, white", and the image is accurately reproduced.
[0085]
On the other hand, when the image data receiving device that cannot know the changed value of the encoded interval receives and decodes the encoded data, the value of the encoded interval is set to “1” and the encoded data is set to “1”. Decoding is performed based on “0.58”. That is, the image is recognized as an image in which the area is converged near the point indicated by the broken line A ′ in FIG. As a result, the pixel becomes “100”, that is, “black, white, white”, and the third and subsequent pixels are decoded as different image data. That is, the original document image is decoded as a different image, and the original image is not reproduced.
[0086]
As described above, only the image data receiving device that can know the changed value of the encoding interval can decode the image data as a correct image. In other words, in a receiving device that cannot know the value of the changed encoding interval, accurate decoding of image data is not possible, and thus concealment can be achieved.
[0087]
As described above, in the present embodiment, if the algorithm of the related art (arithmetic coding by QM-coder) is executed, the image data can be concealed as it is. That is, the image data can be concealed in parallel with the execution of the encoding process without performing any special concealment processing. Furthermore, since the steps of compression (encoding) and concealment can be performed in a single process, the concealed image data can be converted while the processing time and compression ratio are almost unchanged as compared with the case of only normal compression processing. Obtainable. In particular, when a random value is used as the value of the encoding interval, confidentiality can be further improved.
[0088]
Further, in the present embodiment, when notifying the value of the encoding interval changed by the interval changing unit 26 to the facsimile / e-mail device 11 of the other party, an encryption creating unit 25 for encrypting the value of the encoding interval is provided. Let me. Therefore, extremely high confidentiality can be obtained due to a synergistic effect between the encryption of the value of the encoding interval and the concealment of the image data due to the change of the value of the encoding interval. Also, since only information having a relatively small data amount, such as an encoded interval value, is encrypted, it is possible to improve the confidentiality and avoid a prolonged processing time without increasing the processing time and the overall communication amount. It is possible to achieve both.
[0089]
-Other embodiments-
In the above-described embodiment, a case has been described in which the present invention is applied to the facsimile / e-mail device 11 having both the function as the image data transmitting device and the function as the image data receiving device. The present invention is not limited to this, and can be applied to an apparatus having only an image data transmitting function or an apparatus having only an image data receiving function.
[0090]
In addition, the present invention is not limited to a device having both a function as a normal facsimile device, a function as an e-mail device, and a function as an Internet facsimile device, and may be applied to a device having at least one of these functions. Is also possible.
[0091]
In the above-described embodiment, a case has been described in which the present invention is applied to the facsimile / e-mail device 11 that constructs a LAN. The present invention is not limited to this, and can be applied to a device directly connected to a public telephone line or the like without constructing a network.
[0092]
Further, the value of the encoding interval may be changed and set for each transmission of image data, or may be changed and set for each page in the case of simultaneously transmitting image data over a plurality of pages.
[0093]
In addition, in the above-described embodiment, the case where the value of the encoding interval is displayed in the decimal system is described, but the value may be displayed in the binary system or the like.
[0094]
Further, in the above-described embodiment, the value of the encoding interval is automatically set by the facsimile / e-mail device 11, but the setting by the user may be made possible.
[0095]
【The invention's effect】
As described above, in the present invention, the value of the encoding interval, which is a parameter of the algorithm used in the process of the arithmetic encoding process of the JBIG system, is made variable, and the value of the The confidentiality function can be demonstrated. Therefore, only the receiving device that can know the value of the changed encoding interval can accurately decode the image data, thereby achieving concealment.
[0096]
As described above, according to the present invention, if the algorithm of the related art (arithmetic coding by QM-coder) is executed, the image data can be concealed as it is, so that the coding can be performed without performing any special concealment processing. The concealment of image data can be performed in parallel with the execution of the conversion process.
[0097]
In addition, since the compression (encoding) and concealment steps can be performed in a single process, concealed image data is obtained while the processing time and compression ratio are almost unchanged as compared with the case of only normal compression processing. Thus, the encoding process and the concealment process can be performed with high efficiency. In particular, when a random value is used as the value of the encoding interval, confidentiality can be further improved.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating a schematic configuration of a network constructed by a facsimile / e-mail device according to an embodiment.
FIG. 2 is a block diagram showing an electrical configuration of the facsimile / e-mail device.
FIG. 3 is a diagram illustrating a data configuration when encoding interval value information is provided to a comment marker.
FIG. 4 is a diagram showing a case where a value of an encoding interval is stored in header information of an electronic mail.
FIG. 5 is a diagram illustrating a case where a value of an encoding interval is stored in a body of an electronic mail.
FIG. 6 is a flowchart illustrating an operation procedure at the time of facsimile transmission.
FIG. 7 is a flowchart illustrating an operation procedure when receiving image data.
FIG. 8 is a diagram for explaining the principle of arithmetic coding processing when the value of a coding interval is set to “0.8”.
9 is a diagram illustrating a state in which the image data arithmetically encoded in FIG. 8 is arithmetically decoded with the value of an encoding interval being “1”.
FIG. 10 is a diagram illustrating a schematic configuration of a QM-coder.
FIG. 11 is a diagram for explaining the principle of arithmetic coding processing according to a conventional example in which the value of a coding interval is set to “1”.
[Explanation of symbols]
11 Facsimile / E-mail device
(Image data transmitting device, image data receiving device, image data transmitting / receiving device) 21 Encoding / decoding control section (arithmetic encoding means, arithmetic decoding means)
22 LAN control unit (transmission means)
24 Network control unit (transmission means)
25 Encryption creation unit (encryption means)
26 Interval change unit (interval change means)
27 Notification section (notification means)

Claims (9)

Image data transmission comprising: arithmetic coding means for performing JBIG arithmetic coding on image data; and transmission means for transmitting transmission data including the arithmetically coded image data to an image data receiving apparatus. In the device,
An image data transmitting apparatus comprising an interval changing means for changing a value of a coding interval used in the arithmetic coding of the JBIG method in the arithmetic coding means. Image data comprising arithmetic coding means for performing arithmetic coding by QM-coder on image data, and transmission means for transmitting transmission data including the arithmetically coded image data to an image data receiving apparatus In the transmitting device,
An image data transmitting apparatus comprising an interval changing means for changing a value of a coding interval used in arithmetic coding by QM-coder in the arithmetic coding means. The image data transmitting device according to claim 1, wherein
An image data transmitting device, comprising: a notifying unit that includes, in transmission data, notification information for notifying the image data receiving device of the value of the encoding interval changed by the interval changing unit. The image data transmitting device according to claim 1, wherein
An image data transmitting device, comprising: an encrypting unit that encrypts a value of an encoded interval when notifying an image data receiving device of a value of an encoded interval changed by an interval changing unit. The image data transmitting device according to claim 3,
The image data transmitting apparatus, wherein the notifying means is configured to notify the value of the encoding interval changed by the interval changing means to the image data receiving apparatus by a comment marker in the transmission data. The image data transmitting device according to claim 3,
The image data transmitting device, wherein the notifying unit is configured to store the value of the encoding interval changed by the changing unit as information of an electronic mail. The image data transmitting device according to claim 3,
The image data transmitting device, wherein the notifying unit is configured to notify the value of the encoding interval changed by the changing unit to the image data receiving device using a facsimile communication procedure signal. An image data receiving apparatus for receiving encoded image data transmitted from the image data transmitting apparatus according to any one of claims 1 to 7,
An image data receiving apparatus, comprising: arithmetic decoding means for decoding received encoded image data based on a value of an encoding interval changed by an interval changing means. The image data transmitting apparatus according to any one of claims 1 to 7 has an arithmetic coding function and a transmitting function, and the image data receiving apparatus according to claim 8 has a receiving function and an arithmetic decoding function. An image data transmission / reception device, comprising:

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