KR20170107945A - CRUM chip and image forming device for communicating mutually, and method thereof - Google Patents

Abstract

An image forming apparatus is disclosed. The present apparatus includes a main body including a main controller for controlling the operation of the image forming apparatus, a consumable unit mounted on the main body so as to be able to communicate with the main controller, and a CRUM for storing usage information and characteristic information of the consumable unit Customer Replaceable Unit Monitoring) chip. Here, the main controller and the CRUM chip exchange signals including data and integrity check data with each other. Here, the integrity check data is generated by cumulatively reflecting the integrity check data included in the previous signal. Thus, secure communication can be achieved.

Description

[0001] The present invention relates to a CRUM chip, an image forming apparatus, and a communication method therefor.

The present invention relates to a CRUM chip, an image forming apparatus and a communication method thereof, and more particularly, to a CRUM chip, an image forming apparatus, and a communication method thereof for checking integrity using integrity check data in a communication process.

With the spread of computers, the penetration rate of computer peripherals is increasing day by day. As a representative example of a computer peripheral device, there are an image forming apparatus such as a printer, a facsimile, a scanner, a copying machine, a multifunction peripheral, and the like.

Image forming apparatuses use ink or toner to print an image on a paper. The ink or toner is used every time the image forming operation proceeds, and becomes exhausted when it is used for a predetermined time or more. In this case, the unit for storing the ink or toner needs to be newly replaced. The parts or components that can be replaced during the use of the image forming apparatus are referred to as a consumable unit or a replaceable unit. For convenience of description, the term " consumable unit " is used in this specification.

As described above, in the consumable unit, in addition to the units to be replaced due to the depletion of ink or toner, there are units which are replaced for reasons that the characteristics are changed and the good print quality can not be expected. That is, in addition to the color-by-color developing device, parts such as an intermediate transfer belt may correspond to a consumable unit.

Specifically, in the case of a laser image forming apparatus, a charging unit, a transferring unit, a fixing unit, or the like is used, and various kinds of rollers, belts and the like used in each unit may be worn or deteriorated if used for a limited life. As a result, the image quality can be remarkably reduced. The user must replace each constituent unit, that is, the consumable unit, at a proper replacement time so that the printing operation can be performed with a clean image.

Recently, in order to properly manage the consumable unit, a memory is attached to the consumable unit itself so that information can be exchanged with the main body of the image forming apparatus.

That is, various usage information such as the number of prints of the image forming apparatus, the number of output dots, the expiration date, and the like can be recorded in the memory of the consumable unit itself, and the replacement time of the consumable unit can be accurately managed.

For this information management, the main controller provided in the main body of the image forming apparatus and the memory unit provided in the consumable unit communicate with each other. However, there are many variables in the communication process. For example, there may be noise interference generated by an electronic circuit or a motor provided in the image forming apparatus, or there may be an attack by a hacker trying to control the main controller or the memory unit for malicious purposes.

Due to these variables, the communication data can be changed. For example, when the job is completed, information such as the number of printed pages, the number of dots, the amount of remaining toner, and the like is transferred to the main controller and copied to the nonvolatile memory of the main controller. In this case, if the data is read with an incorrect value such as 0xFFFFFFFF, the main controller is at risk of recognizing that the consumable unit has reached its end of life. In this case, the consumable unit is no longer usable. Conversely, even for a consumable unit that has reached its end of life, the hacker can reset the consumable usage information to zero for malicious purposes to make the consumable unit reproducible. As a result, a consumable unit having a short life span is used, which may cause problems such as failure of the image forming apparatus and image quality deterioration.

Accordingly, a need has arisen for a technique capable of effectively checking the communication error between the consumable unit and the image forming apparatus and ensuring the data stability.

An object of the present invention is to provide a CRUM chip, an image forming apparatus, and a communication method thereof, which can achieve communication safety using integrity check data.

According to an aspect of the present invention, there is provided an image forming apparatus including a main body including a main controller for controlling an operation of the image forming apparatus, a consumable unit mounted on the main body for communicating with the main controller, And a CRUM chip (Customer Replaceable Unit Monitoring Chip) provided in the consumable unit and storing usage information and characteristic information of the consumable unit.

Here, the main controller and the CRUM chip transmit / receive data and signals including integrity check data for the data to / from each other, and the integrity check data is generated by cumulatively reflecting the integrity check data included in the previous signal .

Meanwhile, the main controller and the CRUM chip may separate the integrity check data from the received signal when the signal to which the integrity check data is added is received, and the integrity check data generated by itself from the remaining data, The integrity check data is compared to check the integrity of the signal, and if it is determined to be integrity, the signal can be temporarily stored.

Here, the main controller and the CRUM chip may be configured such that when one image forming job is completed, the main controller and the CRUM chip use the integrity check data included in the last received signal in the image forming job, The integrity of the entire signal is finally checked, and if it is determined that the entire signal is integrity, the signals temporarily stored can be stored.

Meanwhile, the data included in the signal may include at least one of command, recording object information, task execution result information according to the command, integrity check result information about a previous received signal, and indicator information for indicating the position of the integrity check data . The integrity check result information may be excluded from signals initially transmitted between the main controller and the CRUM chip.

The integrity check data may be a result of logical operation of the data, a result value generated by applying a predetermined equation to the data, or an encryption result value obtained by encrypting the data.

Meanwhile, an image forming apparatus according to an embodiment of the present invention includes a data processing unit for generating data to be transferred to a CRUM chip mounted on a consumable unit that can be mounted on the image forming apparatus, An interface for transmitting a first signal including the data and the first integrity check data to the CRUM chip and receiving a second signal corresponding to the first signal from the CRUM chip, An inspection unit for separating the second integrity check data included in the second signal and checking the integrity of the second signal and a controller for performing subsequent communication according to the inspection result of the inspection unit.

Here, the second integrity check data may be generated by cumulatively reflecting the first integrity check data.

The checking unit may generate data to be compared using the remaining data included in the second signal, compare the second integrity check data separated from the second signal with the comparison data, The integrity of the signal can be checked. Here, the controller may stop the subsequent communication if it is determined that the second signal is in an error state.

The image forming apparatus may further include a temporary storage unit for temporarily storing the data determined to be integrity and the integrity check data.

The generation unit may generate third integrity check data based on the subsequent data and the second integrity check data if there is subsequent data to be transmitted to the CRUM chip when the second signal is integrity,

The interface unit may transmit a third signal including the third integrity check data and the subsequent data to the CRUM chip.

When the image forming job is completed, the checking unit checks the integrity of the entire signal received in the image forming job performing process using the final integrity check data included in the signal finally received in the image forming job performing process Can be inspected.

The image forming apparatus may further include a storage unit for storing data temporarily stored in the temporary storage unit when it is determined that the entire signal is integrity as a result of the final inspection.

In addition, the data may include at least one of command, recording object information, task execution result information according to the command, integrity check result information about a previous received signal, and indicator information for indicating the position of the integrity check data . The integrity check result information may be excluded from a signal transmitted first with the CRUM chip.

Meanwhile, the integrity check data may be a result of logical operation of the data, a result value generated by applying a predetermined equation to the data, or an encryption result value obtained by encrypting the data.

According to an embodiment of the present invention, there is provided a CRUM chip mountable on a consumable unit of an image forming apparatus, the CRUM chip including first data and first integrity check data for the first data from the main body of the image forming apparatus, 1) signal, an inspection unit for separating the first integrity check data from the first signal to check the integrity of the first signal, and an inspection unit for inspecting the integrity of the first signal if the first signal is included in the first signal A data processing unit for generating the second data when there is a second data to be transmitted to the main body of the image forming apparatus, And a second integrity check data generating unit that generates second integrity check data using the first integrity check data, It includes a storage unit for writing the temporarily stored data to the control section and the temporary storage unit for controlling the interface unit to send a second signal to the main body of the image forming apparatus including the data.

Here, the checking unit may generate data to be compared using the remaining data included in the first signal, compare the second integrity check data separated from the second signal with the data to be compared, It is judged that the second signal is an integrity, and if it is inconsistent, it can be judged as an error state.

Meanwhile, the checking unit may perform an integrity check on the third signal when a third signal including third integrity check data generated by cumulatively reflecting the second integrity check data is received through the interface unit,

When the image forming job is completed, the final integrity check data contained in the last received signal in the image forming job performing process can be used to finally check the integrity of the entire signal received in the image forming job performing process.

In this case, the controller may store the data temporarily stored in the temporary storage unit in the storage unit if it is determined that the entire signal is integrity as a result of the final inspection.

The first data or the second data may include at least one of command, recording object information, task execution result information according to the command, integrity check result information about a previous received signal, and indicator information for informing the position of the integrity check data At least one,

The integrity check result information may be excluded from a signal transmitted first with the CRUM chip.

The integrity check data may be a result of logical operation of the data, a result value generated by applying a predetermined equation to the data, or an encryption result value obtained by encrypting the data.

According to another aspect of the present invention, there is provided a communication method of an image forming apparatus including a main body having a main controller and a consumable unit having a CRUM chip communicable with the main controller, Generating first integrity check data using the generated data, transmitting a first signal including the data and the first integrity check data to the CRUM chip, 1 signal, and checking the integrity of the second signal by separating the second integrity check data included in the second signal. Here, the second integrity check data may be generated by cumulatively reflecting the first integrity check data.

The checking step may include separating the second integrity check data from the second signal, generating comparison target data using the remaining data from which the second integrity check data has been separated, Comparing the separated second integrity check data with the comparison object data, and if it is determined that the second integrity check data is identical to the second integrity check data, determining that the second signal is in an integrity state;

In this case, if it is determined that the second signal is an integrity, temporarily storing the data of the second signal and the second integrity check data.

Generating third integrity check data based on the subsequent data and the second integrity check data if there is subsequent data to be transmitted to the CRUM chip; generating third integrity check data based on the third integrity check data and the subsequent data 3 signal to the CRUM chip.

Finally, when the image forming job is completed, final checking of the integrity of the entire signal received in the image forming job performing step using the final integrity check data included in the signal finally received in the image forming job performing step The method may further include storing the temporarily stored signals when the final signal is determined to be integrity.

The data includes at least one of command, recording object information, task execution result information according to the command, integrity check result information on a previous received signal, and indicator information for indicating the position of the integrity check data, The integrity check result information can be excluded from the signal transmitted first with the CRUM chip.

The integrity check data may be a result of logical operation of the data, a result value generated by applying a predetermined equation to the data, or an encryption result value obtained by encrypting the data.

According to another aspect of the present invention, there is provided a communication method of a CRUM chip that can be mounted on a consumable unit of an image forming apparatus, comprising the steps of: receiving first data and first integrity check data for the first data from a main body of the image forming apparatus; The method comprising the steps of: receiving a first signal containing a first integrity check data, separating the first integrity check data from the first signal to check the integrity of the first signal; A step of temporarily storing the data included in the signal and the first integrity check data, generating second data when there is second data to be transmitted to the main body of the image forming apparatus, And generating second integrity check data using the first integrity check data, and generating the second integrity check data using the second integrity check data And transmitting the second signal to the main body of the image forming apparatus.

The inspecting step may include separating the first integrity check data from the first signal, generating comparison target data using the remaining data included in the first signal, separating the first integrity check data from the first signal, Comparing the second integrity check data with the comparison target data, and if it is determined that the second integrity check data and the comparison target data match, determining that the second signal is an integrity, and if not, determining that the second signal is in an error state.

Performing a integrity check on the third signal when the third signal including the third integrity check data generated by cumulatively reflecting the second integrity check data is received from the main body of the image forming apparatus; .

A final check of the integrity of the entire signal received in the image forming job execution process using the final integrity check data included in the last received signal in the image forming job process when the image forming job is completed, The method may further include storing the signals temporarily stored in the temporary storage unit when the final signal is determined to be integrity.

The first data or the second data may include at least one of command, recording object information, task execution result information according to the command, integrity check result information about a previous received signal, and indicator information for informing the position of the integrity check data And may include at least one.

In this case, the integrity check result information may be excluded from the signal transmitted first with the CRUM chip.

The integrity check data may be a result of logical operation of the data, a result value generated by applying a predetermined equation to the data, or an encryption result value obtained by encrypting the data.

INDUSTRIAL APPLICABILITY As described above, according to various embodiments of the present invention, the integrity check data used in previous communications can be cumulatively used to secure the safety of the entire communication. Thus, the information of the consumable unit and the image forming apparatus can be managed safely.

1 is a block diagram showing the configuration of an image forming apparatus according to an embodiment of the present invention;
2 is a timing diagram for explaining a communication process between a main controller and a CRUM chip in an image forming apparatus according to an embodiment of the present invention;
3 is a timing diagram for specifically explaining a process of checking the integrity of a signal using integrity check data,
4 is a timing diagram for explaining a communication process between a main controller and CRUM chips in an image forming apparatus according to another embodiment of the present invention;
5 is a block diagram showing a configuration of an image forming apparatus equipped with a consumable unit,
6 and 7 are block diagrams showing the configuration of an image forming apparatus according to various embodiments of the present invention,
8 is a block diagram illustrating a configuration of a CRUM chip according to an embodiment of the present invention,
9 and 10 are flowcharts for explaining a communication method according to various embodiments of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing a configuration of an image forming apparatus according to an embodiment of the present invention. 1, the image forming apparatus includes a main body 100, a main controller 110 provided in the main body 100, and a consumable unit 200 that can be mounted on the main body 100. As shown in Fig. Here, the image forming apparatus may be implemented by various types of apparatuses capable of forming images on paper or various recording media such as a printer, a scanner, a multifunction apparatus, a facsimile, a copying machine,

The main controller 110 is mounted on the main body 100 of the image forming apparatus, and controls the overall functions of the image forming apparatus.

The consumable unit 200 may be various types of units mounted on the main body 100 of the image forming apparatus and directly or indirectly involved in the image forming job. For example, in the case of a laser image forming apparatus, a charging unit, an exposure unit, a developing unit, a transferring unit, a fixing unit, various rollers, a belt, an OPC drum and the like can be consumable units. In addition, Various types of units that are required to be replaced may be defined as the consumable unit 200.

As described above, the life span of each consumable unit 200 is determined. Accordingly, the consumable unit 200 includes a CRUM chip (Customer Replaceable Unit Monitoring chip) 210 so that replacement can be made at an appropriate time.

The CRUM chip 210 is mounted on the consumable unit 200 and records various information. The CRUM chip 210 includes a memory. Therefore, the CRUM chip 210 may be referred to as various names such as a memory unit, a CRUM memory (Customer Replaceable Unit Monitoring memory), and the like, but the CRUM chip 210 will be described herein as a CRUM chip 210 for convenience of explanation.

The memory provided in the CRUM chip 210 may store various characteristic information on the consumable unit 200, the CRUM chip 210 itself, the image forming apparatus, and the like, and usage information or programs related to the execution of the image forming job.

Specifically, various programs stored in the CRUM chip 210 may include an O / S (Operating System) program, an encryption program, and the like as well as general applications. The characteristic information includes information on the manufacturer of the consumable unit 200, information on the manufacturer of the image forming apparatus, apparatus name of the attachable image forming apparatus, information on the date and time of manufacture, serial number, model name, An encryption key, an encryption key index, and the like. In addition, the usage information may include information on how many sheets have been printed so far, how many remaining sheets can be printed, how much toner is remaining, and the like. The characteristic information may be otherwise named as unique information.

For example, information such as the following table may be stored in the CRUM chip 210.

General Information OS Version
SPL-C Version
Engine Version
USB Serial Number
Set Model
Service Start Date CLP300_V1.30.12.35 02-22-2007
5.24 06-28-2006
6.01.00 (55)
BH45BAIP914466B.
DOM
2007-09-29 Option RAM Size
EEPROM Size
USB Connected (High) 32 Mbytes
4096 bytes
Consumables Life Total Page Count
Fuser Life
Transfer Roller Life
Tray1 Roller Life
Total Image Count
Imaging Unit / Deve Roller Life
Transfer Belt Life
Toner Image Count 774/93 Pages (Color / mono)
1636 Pages
864 Pages
867 Pages
3251 Images
61 Images / 19 Pages
3251 Images
14/9/14/19 Images (C / M / Y / K) Toner Information Toner Remains Percent
Toner Average Coverage 99% / 91% / 92% / 100% (C / M / Y / K)
5% / 53% / 31% / 3% (C / M / Y / K) Consumables Information Cyan Toner
Magenta Toner
Yellow Toner
Black Toner
Imaging unit SAMSUNG (DOM)
SAMSUNG (DOM)
SAMSUNG (DOM)
SAMSUNG (DOM)
SAMSUNG (DOM) Color Menu Custom Color Manual Adjust (CMYK: 0,0,0,0) Setup Menu Power Save
Auto Continue
Altitude Adj. 20 Minutes
On
Plain

As shown in the above table, the memory of the CRUM chip 210 may store not only general information on the consumable unit 200 but also information on the life of the consumable, information, setup menu, and the like. Also, the memory may store an O / S provided for use in the consumable unit separately from the main body of the image forming apparatus.

In addition, the CRUM chip 210 may further include a CPU (not shown) capable of managing the memory, executing various programs stored in the memory, and communicating with the main body of the image forming apparatus or the controller of the other apparatus .

The CPU can drive the O / S stored in the memory of the CRUM chip 210 to perform the initialization of the consumable unit 200 itself, separately from the initialization of the image forming apparatus. Further, the CPU may perform authentication with the main body of the image forming apparatus during initialization is completed or initialized. Further, after the authentication is completed, encrypted data communication may be performed with the main body of the image forming apparatus. In this case, various commands and data transmitted from the image forming apparatus main body can be encrypted and transmitted according to an arbitrary encryption algorithm.

Specifically, the CPU determines whether or not the power of the image forming apparatus on which the consumable unit 200 is mounted is turned on, the consumable unit 200 is detached, and then the body 100 of the image forming apparatus is again It is possible to perform initialization by itself in addition to the initialization of the main controller 110. [ Initialization is performed by initializing various application programs used in the consumable unit 200, calculating confidential information required for data communication with the main controller 110 after initialization, setting up communication channels, initializing memory values, ) Internal register value setting, internal and external clock signal setting, and so on.

Here, the register value setting means setting the function register values in the consumable unit 200 so that the consumable unit 200 operates in accordance with various functional states previously set by the user. The internal and external clock signal setting means a task of adjusting the frequency of the external clock signal provided from the main controller 110 of the image forming apparatus to match the internal clock signal used by the CPU in the consumable unit 200.

In addition, the self-replacement timing check can be a work for grasping the remaining amount of toner or ink used up to this time and notifying the main controller 110 side of the timing of the final depletion. Accordingly, if it is determined that the toner remaining amount is already exhausted in the initialization process, the consumable unit 200 may be notified to the main controller 110 itself after the initialization is completed. In addition, since the consumable unit 200 has its own O / S, various types of initialization can be performed according to the type and characteristics of the consumable unit 200.

In this way, when the image forming apparatus is powered on, the main controller 110 is stored in the memory unit 210 before the main controller 110 requests the communication with the unit 200. In this case, You can check the remaining amount of consumables or the number of refills. As a result, the time for noticing the supply shortage can be much faster than the conventional one. For example, in the case of a toner shortage, the user can operate to turn on the toner-saving mode immediately after power-on to perform image formation. The same is true when only a specific toner is lacking.

The CPU does not respond to the command of the main controller 110 until the initialization is completed and completed. The main controller 110 waits for a response while periodically transmitting a command until a response is received.

Accordingly, when a response, i.e., an acknowledgment is received, authentication is performed between the main controller 110 and the CPU. In this case, authentication can be performed between the CRUM unit 210 and the main controller 110 through interaction with the CRUM chip 210 due to its own O / S installed in the CRUM chip 210.

Specifically, the main controller 110 encrypts data or commands for authentication and transmits them to the CRUM chip 210. The transmitted data may include an arbitrary value R1. Here, R1 may be a random value that changes every authentication, or may be a fixed value arbitrarily set. The CRUM chip 210 receiving the data generates a session key using a certain value R2 and the received R1, and generates a MAC (Message Authentication Code) using the generated session key. And transmits a signal including the generated MAC and R 2 to the main controller 110. The main controller 110 generates a session key using the received R2 and R1, generates a MAC using the generated session key, compares the generated MAC with the MAC included in the received signal, 210). Meanwhile, according to various embodiments, digital signature information, key information, and the like may be transmitted and received in the authentication process and used for authentication.

If the authentication is successful, the main controller 110 and the CRUM chip 210 perform encrypted data communication for data management. That is, in the case where a user command is input, or an image forming job is started or completed, the main controller 110 uses a cryptographic algorithm to execute commands and data for performing operations such as data reading and writing And transmits the encrypted data to the CRUM chip 210. The CRUM chip 210 can decode the received command or data and perform operations such as data reading and writing corresponding to the command. The encryption algorithm used in the CRUM chip 210 or the main controller 110 may be a standard encryption algorithm. This encryption algorithm can be changed when the encryption key is disclosed or when security needs to be enhanced. Specifically, various encryption algorithms such as RSA asymmetric key algorithm, ARIA, TDES, SEED, AES symmetric key algorithm, and the like can be used.

As described above, communication between the CRUM chip 210 and the main controller 110 for authentication and data exchange can be performed several times. In each communication, signals are transmitted from the main controller 110 to the CRUM chip 210 or vice versa. In this case, the transmitted signal includes error detection data for checking the integrity of the data included in the signal. The integrity check data is generated by cumulatively reflecting the integrity check data included in the transmitted or received signal in the previous communication.

Authentication 1, authentication 2, authentication 3, ..., authentication n, data communication 1, data communication 2, ..., data communication m between the main controller 110 and the CRUM chip 210, A plurality of communications can be performed together. Signals transmitted at every communication include integrity check data. The integrity check data used in the previous communication is cumulatively reflected in the integrity check data. Specifically, it will be described later in the drawings.

On the side receiving the signal, the integrity check of the signal is checked using the integrity check data included in the signal. Accordingly, if it is determined that the signal is integrity, data and integrity check data included in the signal are temporarily stored. Then, new integrity check data is generated using the subsequent data to be transmitted to the transmitter side and the integrity check data stored in the immediately preceding communication and temporarily stored. Accordingly, a signal obtained by adding new integrity check data to subsequent data is transmitted. Communication including the integrity check data is performed a plurality of times between the main controller 110 and the CRUM chip 210. [ If the last communication is made, a final check using the integrity check data included in the last received signal is performed. As a result of the final inspection, if there is no abnormality, the entire data temporarily stored until then is recorded.

2 is a timing chart for explaining a communication process between the main controller 110 and the CRUM chip 210 according to an embodiment of the present invention. 2, the main controller 110 transmits a first signal 10 including data 1 and integrity check data 1. The CRUM chip 210 receiving the first signal 10 generates the integrity check data 2 using the integrity check data 1 and the data 2 included in the first signal 10. Then, a second signal including data 2 and integrity check data 2 is transmitted to the main controller 110. In this manner, the signals 30, ..., N including the integrity check data generated using the integrity check data in the previous communication are performed a plurality of times.

As the integrity check data, a result value obtained by performing logical operation on data to be transmitted, a result value generated by applying a predetermined mathematical expression to data or an encryption result value obtained by encrypting data may be used.

3 is a diagram for explaining an inspection method using integrity check data. Referring to FIG. 3, when a signal including the data a and the integrity check data a is received from the main controller 110 at step S310, the CRUM chip 210 separates the integrity check data a at step S320.

Then, the integrity check data a 'is generated using the remaining data and the integrity check data transmitted at the time of the previous communication (S330). The integrity check data a 'thus generated is compared with the integrity check data a (S340). If they are identical, the integrity check data a is determined to be integrity (S350). On the other hand, if the mismatch occurs, it is determined that an error has occurred and communication is interrupted (S360). For convenience of explanation, the integrity check data a 'is hereinafter referred to as comparison target data.

If it is determined to be integrity, the integrity check data b is generated using the data b to be transmitted and the integrity check data a (S370). Accordingly, the signal including the data b and the integrity check data b is transmitted to the main controller 110 (S380).

3, the inspection process performed in the CRUM chip 210 has been described. However, the same process may be performed in the main controller 110 as well. That is, upon receiving the signal including the data b and the integrity check data b, the main controller 110 separates the integrity check data b and performs the check. Since the inspection method is the same as that of S330 to S370, redundant description and illustration are omitted.

Meanwhile, the structure of signals transmitted and received between the main controller 110 and the CRUM chip 210 can be variously designed. That is, the data included in the signal may include at least one of command, recording object information, operation result information according to the command, integrity check result information on the previous received signal, and indicator information for indicating the location of the integrity check data . Here, the integrity check result information may be excluded from the signal initially transmitted between the main controller 110 and the CRUM chip 210. [

4 is a diagram for explaining a process of checking integrity using a signal of a format different from that of FIG. Referring to FIG. 4, the main controller 110 transmits a signal including data and integrity check data 1 (S410). Here, the read command data 1 (Read Command (CMD) data 1) and the indicator U1 are included in the data. The read command data 1 includes not only commands but also read targets or memory addresses. U1 means indicator information following read command data 1. [ The indicator information U1 indicates a symbol for informing the parsing position of the integrity check data in the signal. The indicator information may be represented by a fixed number of bytes. For example, five bytes may be used for the indicator information. On the other hand, the size of the read command data 1 is variable according to the content of the data, and accordingly, the size of the integrity check data 1 is also variable.

When the signal is received, the CRUM chip 210 performs an integrity check using the integrity check data 1 included in the signal (S415). Then, integrity check data 2 is generated using the data to be transmitted and the integrity check data 1, and a signal including the integrity check data 2 is transmitted (S420). 4, the transmitted signal includes read data 1, which is data read from the memory provided in the consumable unit 100 in accordance with the read command data 1, Result data 2 indicating the result, indicator U2, and integrity check data 2 are included.

The main controller 110 separates the integrity check data 2 from the received signal and performs an integrity check (S425). If there is a subsequent read command data 3, the integrity check data 3 is generated using the read command data 3 and the integrity check data 2, and then the signal including the read command data 3, the indicator U3, and the integrity check data 3 is To the CRUM chip 210 (S430). 4, communication using the plurality of integrity check data 4, 5, 6, T1, and T2 is performed (S440, S450, S460, S470, and S485), and the integrity check is performed (S435, S445, S455, S465). On the other hand, when the CRUM chip 210 receives the last communication signal (S470), the CRUM chip 210 transmits the integrity check data T1 included in the last communication signal, The integrity is finally checked (S475). If it is determined as a result of the final inspection, the temporarily stored data is stored in a non-volatile memory (S480). Likewise, when the last communication signal is transmitted from the CRUM chip 210 (S485), the main controller 110 performs the entire integrity check using the integrity check data T2 included in the last communication signal (S490). Accordingly, if it is determined to be integrity, the temporarily stored data is stored in the nonvolatile memory (S495).

On the other hand, the integrity check data used in this communication process is generated by cumulatively reflecting the integrity check data used in the previous communication.

In one example, the integrity check data can be processed as follows.

Integrity check data 1 = E (Read CMD Data 1 | U1)

Integrity check data 2 = E (Read CMD Data 2 | Result Data 2 | U2 | integrity check data 1)

Integrity check data 3 = E (Read CMD Data 3 | U3 | integrity check data 2)

Integrity check data 4 = E (Read CMD Data 4 | Result Data 4 | U4 | integrity check data 3)

Integrity check data 5 = E (Write CMD Data 5 | U5 | integrity check data 4)

Integrity check data 6 = E (Result data 6 | U6 | integrity check data 5)

Integrity check data T1 = E (Write CMD Data L1 | U-T1 | Integrity check data T1-1)

Integrity check data T2 = E (Result Data L2 | U-T2 | Integrity check data T1)

In the above equations, E () denotes a function for obtaining a result value by applying a preset formula. The integrity check data may be obtained by applying various logical operations such as summing, XOR (eXclusive OR), etc. to the previous integrity check data and the entire data to be transmitted, or by applying data to the other main controller 110 and the CRUM chip 210 , A result value calculated by substituting the above-mentioned various encryption algorithms, and the like.

5 shows a configuration of an image forming apparatus in which a plurality of consumable units 200-1, 200-2, ..., 200-n are mounted in a main body 100 according to an embodiment of the present invention.

5, the image forming apparatus includes a main controller 110, a user interface unit 120, an interface unit 130, a memory unit 140, a plurality of consumable units 200-1, 200-2, 200-n.

The user interface unit 120 receives various commands from the user or displays various information to inform the user. The user interface unit 120 may include an LCD or LED display, at least one button, a speaker, etc., and may also include a touch screen.

The interface unit 130 is connected to a host PC or various external devices through wired or wireless communication. The interface unit 130 may include various types of interfaces such as a local interface, a Universal Serial Bus (USB) interface, and a wireless network interface.

The memory unit 140 stores various programs, data, and the like necessary for driving the image forming apparatus.

The main controller 110 serves to control the overall operation of the image forming apparatus. Specifically, the main controller 110 processes data received through the interface unit 130 and converts the processed data into a format capable of image formation.

Then, the main controller 110 performs an image forming job on the converted data using the plurality of consumable units 200-1, 200-2, ..., 200-n. Here, the consumable unit may be variously provided according to the type of the image forming apparatus. As described above, in the case of a laser printer, a charging unit, an exposure unit, a developing unit, a transferring unit, a fixing unit, various rollers, a belt, an OPC drum, or the like can be a consumable unit.

On the other hand, the first CRUM chip to the n-th CRUM chips 210-1, 210-2, ..., 210-n are connected to the respective consumable units 200-1, 200-2, Respectively.

Each CRUM chip may include a memory and a CPU. Alternatively, depending on the embodiment, a crypto module, a temper detector, an interface, a clock unit (not shown) for outputting a clock signal, a random value generator for generating a random value for authentication, (Not shown) may be further included.

A crypto unit (not shown) supports an encryption algorithm so that a CPU (not shown) can perform authentication or encrypted communication with the main controller 110. Specifically, the crypto unit can support an algorithm set among four encryption algorithms such as ARIA, TDES, SEED, and AES symmetric key algorithm. In this case, the main controller 110 can also support a corresponding algorithm among the four encryption algorithms. Accordingly, the main controller 110 can recognize what kind of encryption algorithm is used in the consumable unit 200, perform authentication using the encryption algorithm, and then perform encrypted communication. As a result, even if a key (KEY) to which the encryption algorithm is applied to the consumable unit 200 is issued, it can be easily mounted to the main body 100 of the image forming apparatus and can perform encrypted communication.

A temper detector (not shown) is a unit for defending various physical hacking attempts, i.e., tempering. Specifically, it monitors the operating environment such as voltage, temperature, pressure, light, and frequency, and erases or physically disconnects data when there is an attempt such as Decap. In this case, the temper detector may have a separate power source.

Meanwhile, the memory provided in the CRUM chip 210 may include an O / S memory, a nonvolatile memory, a volatile memory, and the like. The O / S memory (not shown) stores O / S for driving the consumables unit 200. In the nonvolatile memory (not shown), various data are stored nonvolatilely. The nonvolatile memory includes electronic signature information, various encryption algorithm information, state information of the consumables unit 200 (e.g., toner remaining amount information, replacement timing information, remaining print count information, etc.), unique information Information on manufacture date, serial number, product model name, etc.), A / S information, and the like can be stored. In particular, data received in the course of communication with the main controller 110 may be stored in the nonvolatile memory.

A volatile memory (not shown) can be used as a temporary storage space required for operation. In the volatile memory, data judged to be complete at every communication and integrity check data used for the judgment can be temporarily stored.

The interface unit (not shown) serves to connect the CPU and the main controller 110. Specifically, it can be implemented by a serial interface or a wireless interface. Particularly, since the serial interface uses a smaller number of signals than the parallel interface, it has a cost reduction effect, and is particularly suitable for a noise-prone operation environment such as a printer.

As described above, each consumable unit may be provided with a CRUM chip. Each CRUM chip can communicate with the main controller and other CRUM chips. At the time of communication, the integrity check data used in the previous communication is cumulatively reflected and new integrity check data generated is transmitted.

6 is a block diagram showing a detailed configuration example of an image forming apparatus according to an embodiment of the present invention. 6, the image forming apparatus includes a main controller 110 and an interface unit 130. The main controller 110 includes a data processor 111, a generator 112, an examiner 113, a controller 114 ).

The data processing unit 111 generates data to be transmitted to a CRUM chip mounted on a consumable unit that can be mounted on the image forming apparatus. Here, the data includes at least one of a command and information to be processed by the command. That is, in the case of the read command, the memory address to be read or the information on the read object can be transmitted together. Also, in the case of a write command, information to be recorded can be transmitted together. The data processing unit 111 can directly output or encrypt the data. In addition, various commands such as a command for authentication and information related to the command can be generated in the data processing unit 111. [ These commands and information may be generated from time to time before, during, or after the execution of the image forming job. For example, when the image forming apparatus is turned on, the consumable unit 200 is detached and then re-mounted, or when a start command for an image forming job is input, the main controller 110 controls the consumable unit 200, It is possible to transmit an authentication command or a read command. Accordingly, various information managed in the consumable unit 200 can be checked and authenticated or stored in the memory unit 140 of the main body of the image forming apparatus 100.

During or after completion of the image forming job, the data processing section 111 obtains the consumables consumed in the image forming job, that is, the information about the ink or toner, the number of printed pages, the number of printed dots, History information and the like in the consumable unit 200, the write command and the corresponding information can be generated.

The generation unit 112 generates integrity check data using the data output from the data processing unit 111. Specifically, the data output from the data processing unit 111 may be simply summed, a logic operation such as XOR may be performed, a substitution may be made in a predetermined mathematical expression, or an encryption algorithm may be used to encrypt the data, . In this case, if the integrity check data used in the previous communication exists, the existing integrity check data is cumulatively reflected together to generate integrity check data.

The integrity check data generated by the generation unit 112 is added to the data generated by the data processing unit 111 and transmitted to the interface unit 130. 6, the output of the data processing unit 111 may be provided directly to the interface unit 130 or may be provided to the multiplexer (not shown) have. When the multiplexer is provided, the output of the generating unit 112 may also be provided to the multiplexer, and may be transmitted to the interface unit 130 in the form of a signal including data and integrity check data.

The interface unit 130 transmits a signal including the data and the first integrity check data to the CRUM chip 210.

Also, the interface unit 130 can receive a response signal from the CRUM chip 210. [ A signal transmitted from the interface unit 130 is referred to as a first signal and a signal received from the CRUM chip is referred to as a second signal. The second integrity check data included in the second signal is data generated by cumulatively reflecting the first integrity check data.

The checking unit 113 separates the second integrity check data included in the second signal received through the interface unit 130 and checks the integrity of the data included in the second signal. More specifically, the checking unit 113 checks whether the second integrity check data has been separated from the remaining data and the integrity check data previously transmitted from the main controller 110 to the CRUM chip 210, Method is applied to generate integrity check data.

The integrity check data thus generated is compared with the second integrity check data separated from the second signal to check whether or not they match. If the check result is found to match, the checking unit 113 determines that the data is integrity, and if the data is inconsistent, determines that the corresponding data is in an error state.

The control unit 114 performs the subsequent communication according to the inspection result of the inspection unit 114. That is, if it is determined that the second signal includes data in the error state, the subsequent communication can be interrupted or retried. On the other hand, if it is determined that the second signal is in the normal state, that is, the integrity state, the subsequent communication is performed.

According to the embodiment, when it is determined that the integrity state is established, the control unit 114 can directly store the corresponding data in the memory unit 140. [

According to another embodiment, the acquired data and the integrity check data may be temporarily stored in each communication and the temporarily stored data may be stored in the memory unit 140 when the final communication is completed.

Fig. 7 shows a configuration of an image forming apparatus according to this embodiment. 7, a memory unit 140 is further included in addition to the main controller 110 and the interface unit 130 including the data processing unit 111, the generating unit 112, the checking unit 113, and the controlling unit 114 . The memory unit 140 includes a temporary storage unit 141 and a storage unit 142.

Accordingly, the data and the integrity check data determined to be integrity can be temporarily stored in the temporary storage unit 141. Temporarily stored integrity check data can be used in the integrity check of the data in the subsequent communication process.

That is, as described above, when the first signal including the first integrity check data is transmitted to the CRUM chip 210 and the second signal for the first signal is transmitted, the checking unit 113 extracts the second integrity check data from the second signal 2 integrity check data, and generates new integrity check data, that is, comparison target data, using the remaining data and the integrity check data stored in the temporary storage unit 141. [ Then, the checking unit 113 compares the generated new integrity check data with the second integrity check data to the temporary storage unit 141 to determine the integrity of the data included in the second signal or the second signal.

On the other hand, if there is subsequent data to be transmitted to the CRUM chip 210 in a state where the second signal is integrity, the generation unit 112 generates the third integrity check data based on the subsequent data and the second integrity check data. Accordingly, the interface unit 130 transmits a third signal including the third integrity check data and the subsequent data to the CRUM chip 210. That is, as described in FIGS. 2 to 4, the main controller 110 and the CRUM chip 210 perform a plurality of communications.

On the other hand, when one image forming job is completed, the checking unit 113 uses the final integrity check data included in the last received signal in the image forming job performing process to check the integrity of the entire signal received in the image forming job performing process Can be finally inspected. That is, as described above, the integrity check data transmitted / received at every communication is generated by cumulatively reflecting the previous integrity check data. Therefore, the final integrity check data includes all of the first integrity check data to the previous integrity check data. Therefore, if it is determined that the data is integrity using the final integrity check data, the entire data temporarily stored is stored in the storage unit 142 of the memory unit 140, since the entire data is determined to be reliable.

Meanwhile, the main controller 110 and the CRUM chip 210 transmit a signal indicating that the initial communication is included in the signal and transmits the signal including the indication of final communication at the time of final communication. Accordingly, the main controller 110 and the CRUM chip 210 store the data in the storage unit 142 by performing the above-mentioned final inspection when the final communication indication is confirmed on the signal received from the counterpart.

This final inspection may be performed when one image forming job is completed, or may be performed in a predetermined time period unit depending on the embodiment. Also, it can be performed when a user command for storing data is inputted, or when a turn-off command is inputted to the image forming apparatus.

6 and 7, the data processing unit 111, the generating unit 112, the checking unit 113, and the controlling unit 114 are included in the main controller 110, but the present invention is not limited thereto. That is, at least one of the data processing unit 111, the generating unit 112, the checking unit 113, and the controlling unit 114 may be provided separately from the main controller 110. 1 to 4, the main controller 110 performs only the original function and the communication with the CRUM chip 210 is performed by the data processing unit 111, the generating unit 112, the checking unit 113, Or may be performed by the control unit 114 or the like.

8 is a block diagram showing a configuration of a CRUM chip 210 according to an embodiment of the present invention. 8, the CRUM chip 210 includes an interface 211, an inspection unit 212, a generation unit 213, a data processing unit 214, a control unit 215, a temporary storage unit 216, a storage unit 217 ).

The interface unit 211 receives the first signal including the first data and the first integrity check data for the first data from the main body of the image forming apparatus, particularly, the main controller 110 mounted on the main body of the image forming apparatus.

The checking unit 212 separates the first integrity check data from the first signal and checks the integrity of the first signal. Since the inspection method of the inspection unit 212 has been described in the above section, a duplicate description will be omitted.

The temporary storage unit 216 temporarily stores the first data and the first integrity check data if the first signal is determined to be integrity.

The data processing unit 214 generates second data when there is second data to be transmitted to the main body of the image forming apparatus.

The generation unit 213 generates the second integrity check data using the generated second data and the first integrity check data.

The control unit 215 controls the interface unit to transmit the second signal including the second data and the second integrity check data to the main body of the image forming apparatus. In addition, the control unit 215 controls the operation of the entire CRUM chip 215. That is, when the CRUM chip itself has the O / S as described above, the control unit 215 can drive the CRUM chip using the O / S. In particular, if the initialization program is stored, the initialization may be performed separately from the main body of the image forming apparatus.

In addition, the control unit 215 performs operations corresponding to various commands received from the main body of the image forming apparatus. That is, when a read command is received, the data stored in the storage unit 217 is read according to the read command, and is transmitted to the image forming apparatus through the interface unit 211. In this process, integrity check data can be added.

On the other hand, if the third signal including the third integrity check data generated by cumulatively reflecting the second integrity check data is received through the interface unit 211, the checking unit 212 checks the integrity of the third signal .

When the image formation job is completed, final integrity inspection is performed on the integrity of the entire signal received in the image forming job execution process, using the final integrity check data included in the last received signal in the image forming job execution process.

If the communication is completed in the integrity state, the data temporarily stored in the temporary storage unit 216 is stored in the storage unit 217.

That is, when the communication ends, the control unit 215 controls the checking unit 212 to perform the final check using the last integrity check data. Accordingly, if it is determined as a result of the final inspection by the inspection unit 212, the control unit 215 stores the data temporarily stored in the temporary storage unit 216 in the storage unit 217.

The operation of the CRUM chip 210 of FIG. 8 is also similar to that of the image forming apparatus of FIG. That is, the main controller 110 of the image forming apparatus and the CRUM chip 210 of the consumable unit 200 perform operations corresponding to each other as described with reference to FIG. 1 to FIG. Accordingly, algorithms for generating integrity check data and inspecting the integrity check data on both sides should be provided in common.

9 is a flowchart illustrating a communication method according to an embodiment of the present invention. The communication method described with reference to FIG. 9 may be performed in the main controller 110 provided in the main body of the image forming apparatus or in the CRUM chip 210 provided in the consumable unit 200.

Referring to FIG. 9, when data to be transmitted is generated (S910), integrity check data is generated using the data (S920). The generation of the integrity check data is the same as described above, so a detailed description thereof will be omitted.

Then, a signal including the generated integrity check data and data is transmitted (S930).

Accordingly, a response signal corresponding to the transmitted signal is received from the other party (S940). The response signal includes new integrity check data generated by cumulatively reflecting the integrity check data transmitted in S930.

Accordingly, the integrity check is performed using the integrity check data included in the response signal (S950).

As described above, according to the simple application of the present invention, integrity of each communication can be judged by cumulatively using previous integrity check data.

10 is a flowchart for explaining a communication method according to a more specific embodiment. Referring to FIG. 10, when data to be transmitted is generated (S1010), integrity check data is generated based on the data (S1020). Then, a signal including data and integrity check data is transmitted (S1030), and a response signal to the signal is received (S1040). Accordingly, the integrity check data is separated from the response signal (S1050).

Then, it is determined whether the integrity check data is integrity using the separated data and the existing integrity check data (S1060).

If it is determined to be integrity, it is temporarily stored (S1070), and if it is an error state, communication is interrupted (S1100) and retry is performed.

On the other hand, if there is subsequent data in the temporarily stored state (S1080), the above-described steps are repeatedly performed. On the other hand, if there is no subsequent data, the temporarily stored data is stored according to the integrity check result of the finally received signal (S1090).

In the above-described various embodiments, the integrity check data is generated by accumulating the integrity check data at the time of previous communication, except for the integrity check data transmitted from the main controller of the image forming apparatus at the time of starting the data communication for the first time. As a result, the integrity check data in the final communication includes all the integrity check data used in the entire communication process. Therefore, accurate data can be recorded.

As a result, the information of the main controller and the CRUM chip can be safely protected from external factors such as noise, contact failure, hacking, and the like occurring during communication.

In the above-described embodiments, the image forming apparatus and the CRUM chip mounted on the consumable unit used in the apparatus have been described. However, the communication method described above can be applied to other types of apparatuses. For example, in the case of communication between a device manufactured for communication with a CRUM chip rather than an image forming apparatus and a CRUM chip, in the case of communication between a general electronic device and a memory mounted on a part used in the device, The present invention is not limited thereto.

The program for performing the communication method according to various embodiments of the present invention can be stored in various types of recording media and used.

Specifically, the code for performing the above-described methods may be stored in a storage medium such as a RAM (Random Access Memory), a flash memory, a ROM (Read Only Memory), an EPROM (Erasable Programmable ROM), an EEPROM (Electronically Erasable and Programmable ROM) Such as a floppy disk, a removable disk, a memory card, a USB memory, a CD-ROM, and the like.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the present invention.

100: main body 110: main controller
200: Consumable unit 210: CRUM chip

Claims (16)

A CRUM memory capable of communicating with an image forming apparatus,
An interface unit for performing communication with the main controller of the image forming apparatus; And
Generating second integrity check data using second data to be transmitted to the main controller and the first integrity check data when the first data and the first integrity check data for the first data are received from the main controller, And a controller for transmitting the second data and the second integrity check data to the main controller. The method according to claim 1,
Wherein,
And checks the integrity of the first data using the first integrity check data and controls the interface unit to transmit the second data and the second integrity check data if the integrity of the first data is confirmed. The method according to claim 1,
And a storage for storing the first integrity check data and the second integrity check data. The method according to claim 1,
Wherein,
When the third integrity check data for the third data and the third data is received from the main controller, fourth integrity check data is generated using the fourth data to be transmitted to the main controller and the first through third integrity check data And transmits the fourth data and the fourth integrity check data to the main controller. 5. The method of claim 4,
Wherein,
And checks the integrity of the third data using the third integrity check data and the first and second integrity check data. The method according to claim 1,
Wherein,
Generating a session key using the first data and the second data,
An authentication process for matching the first table stored in each of the main controller and the CRUM chip when the session key generation is completed, an authentication process for matching the second table stored in each of the main controller and the CRUM chips, And an authentication process for determining mutually conformity between the image forming apparatus and the CRUM chip based on at least one of the first table and the second table. The method according to claim 1,
Wherein the second data comprises:
Wherein the CRUM memory includes at least one of random data, a chip serial number, key related information used in an asymmetric key algorithm, internal information of the CRUM chip, and result data indicating a result of performing an operation performed on the CRUM chip. The method according to claim 1,
Wherein the first data is a first random value,
Wherein the second data comprises a second random value and a MAC (Message Authentication code) generated based on the first random value and the second random value. In a method of operating a CRUM memory,
Upon receiving the first data and the first integrity check data for the first data from the main controller of the image forming apparatus, generates second integrity check data using the second data to be transmitted to the main controller and the first integrity check data ; And
And transmitting the second data and the second integrity check data to the main controller. 10. The method of claim 9,
And checking integrity of the first data using the first integrity check data. 10. The method of claim 9,
And storing the first and second integrity check data. 10. The method of claim 9,
Receiving third integrity check data for the third data and the third data from the main controller;
Generating fourth integrity check data using fourth data to be transmitted to the main controller and the first to third integrity check data; And
And transmitting the fourth data and the fourth integrity check data to the main controller. 13. The method of claim 12,
And checking the integrity of the third data using the third integrity check data and the first and second integrity check data. 13. The method of claim 12,
Generating a session key using the first data and the second data; And
An authentication process for matching the first table stored in each of the main controller and the CRUM chip when the session key generation is completed, an authentication process for matching the second table stored in each of the main controller and the CRUM chips, Sequentially performing an authentication process for determining mutually conformity between the image forming apparatus and the CRUM chip based on at least one of the first table and the second table. A consumable device to be mounted on an image forming apparatus,
A consumable unit mounted on the image forming apparatus; And
And a CRUM memory for communicating with the main controller of the image forming apparatus,
The CRUM memory includes:
Generating second integrity check data using second data to be transmitted to the main controller and the first integrity check data when receiving the first data and the first integrity check data for the first data from the main controller, And transmits the second data and the second integrity check data to the main controller. 16. The method of claim 15,
Wherein the consumable unit is at least one of a charging unit, an exposure unit, a developing cartridge, a transfer unit, and a fixing unit.

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