KR101381746B1 - Black box apparatus for vehicle - Google Patents

Abstract

The present invention relates to a black box apparatus for a vehicle, and more particularly, to a black box apparatus including: a key input unit for outputting a key code according to a driver′s key input; a camera unit for outputting image data captured through a camera installed in at least one direction of front, rear, and side directions of the vehicle; a sensor unit installed in the vehicle, and sensing an impact applied to the vehicle to output a sensing signal; a data storage unit having a plurality of memory cells partitioned into at least two storage regions; a controlling unit for controlling an operation of the camera using the input key code, determining whether a recording state of the camera unit is a normal state or an emergency state and controlling image data to be selectively stored in the storage regions of the plurality of memory cells on the basis of the sensing signal, and outputting a test signal for testing a state of the data storage unit using the input key code; a memory management unit for calculating a percentage of failure memory cells among the plurality of memory cells and outputting the state of the data storage unit corresponding to the failure rate; a display unit for displaying the state of image data and the state of the data storage unit on a display according to the control signal of the controlling unit; a voice output unit for outputting the state of the data storage unit in a voice according to the control signal of the controlling unit; and a data communication unit for transmitting image data or the state of the data storage unit to a driver′s terminal through a control of the controlling unit. In accordance with the black box for the vehicle of the present invention, use of the data storage unit is stable and a rapid decrease in a life cycle may be prevented, so that a performance of the black box is improved.

Description

Black box apparatus for vehicle

The present invention relates to a vehicle black box device, and more particularly, to notify the driver of the defective rate of the memory cell through the memory management unit so that the driver can easily know the state of the data storage unit, and the image data according to the frequency of use of the memory cell. A vehicle black box device in which the service life of the data storage unit is increased by relocating the storage area of the device.

Recently, as the greening situation of the vehicle black box device is adopted as an important evidence in the event of a vehicle accident, fraud using a vehicle, and hit by Sony, the demand for the vehicle black box device is increasing.

Normally, the SD card is used in almost all products to store images. However, if the SD card is not checked for defects or availability, the driver's data is recorded when the driver suddenly encounters an accident while parking or driving the vehicle. There is a problem that the damaged or unrecorded Buddha.

     On the other hand, the vehicle black box device creates a folder in a fixed area of the SD card and stores the data in the corresponding folder for each type and format. There is a problem in that the lifespan of a memory cell having a low frequency is different and a failure rate rapidly increases.

A typical SD card is composed of MLC and TLC, and it is possible to record and delete data 5000 times in case of MLC and 1000 times in case of TLC. For example, an SD car composed of 1GB of MLC ends its life when recorded and deleted as much as 1GB * 5000 times, and there is a problem that a certain period of time must be replaced. In addition, the driver is periodically recommended to format the SD card to recognize this problem, but this also has a cumbersome problem.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems. In particular, it is an object of the present invention to provide a black box device for a vehicle in which the driver can easily know the state of the data storage unit by notifying the driver of the defective rate of the memory cells.

In addition, another object of the present invention is to provide a black box device for a vehicle in which the life span of the data storage unit is increased by relocating the storage area of the image data according to the frequency of use of the memory cell.

The present invention A key input unit for outputting a key code according to a driver's key input, a photographing unit for outputting image data photographed through a camera installed in at least one of front, rear, and side directions of the vehicle, and a shock applied to the vehicle A black box device for a vehicle, comprising: a sensor unit configured to detect a signal and output a detection signal; and a data storage unit having a plurality of memory cells divided into at least two storage areas. And determining whether the recording state of the photographing unit is always or urgent based on the detection signal, and controlling the image data to be selectively stored in the storage areas of the plurality of memory cells. A control unit which outputs a test signal for checking a state of the data storage unit, and inputs the test signal A memory manager for calculating a ratio of defective memory cells among the plurality of memory cells and outputting a state of the data storage unit corresponding to the defective rate; and controlling the state of the image data and the data storage unit according to a control signal of the controller. Transmitting the state of the image data or the data storage unit to the terminal of the driver under the control of the display unit to display on the screen, the audio output unit for outputting the state of the data storage unit in the voice by the control signal of the controller and the control unit Characterized in that it further comprises a data communication unit.

In addition, in the vehicle black box apparatus of the present invention, the memory management unit inputs the test signal of the controller to sequentially write test data according to addresses of the plurality of memory cells and simultaneously read the test data. Detects the bad memory cell, records the address of the bad memory cell, and checks a bad memory cell for outputting a test completion signal when the memory cell of the last address is checked, and inputs the test completion signal to the entire data storage unit. If the defective rate inputted through the defective rate calculating unit and the defective rate calculating unit that calculates and outputs the defective rate occupied by the defective memory cell among the memory cells is less than 50%, normal data is output, and exceeds 50%. If less than%, outputs caution data, and if the defective rate exceeds 70% It is achieved by including a warning signal output for outputting a replacement data.

In particular, in the vehicle black box apparatus of the present invention, the bad memory cell inspection unit sequentially checks according to each address of the plurality of memory cells, but if the written test data and the read test data are the same, the memory of the next address The cell is examined and, if not identical, the corresponding memory cell detects a bad memory cell and records the address of the bad memory cell.

 Further, in the present invention, the data storage unit counts the frequency of use of the memory cell to be used currently arranged in the storage area of the image data under the control of the controller, wherein the frequency of use of the memory cell to be used is counted higher than the first level. In this case, an alarm unit for outputting an unused memory cell confirmation signal for designating the memory cell to be used as an unused memory cell and the unused memory cell confirmation signal are inputted to select the remaining memory cells except for the unused memory cell. The apparatus may further include a storage area relocator configured to designate a storage area of the image data.

The data storage unit may further include a capacity comparison unit that is rearranged through the storage area rearrangement unit and outputs a memory cell capacity comparison signal when the capacity of all the memory cells currently being used corresponds to half of the initial capacity of the data storage unit. The storage area repositioning unit reassigns the storage area of the image data including the unused memory cell to the memory cell being used by inputting the memory cell capacity comparison signal, and the alarm unit previously assigned the memory cell to be used. In the case of including unused memory cells, the unused memory cells may be designated based on a second level higher than the first level.

Since the vehicle black box device according to the present invention can recognize the state of the data storage unit according to the driver's key input, it can solve the anxiety about the failure of the data storage unit, and the driver can recognize the state of the data storage unit in advance so that the stable use is possible. There is a possible effect.

In addition, according to the present invention, by effectively rearranging the storage area of the logically divided image data according to the frequency of use of the memory cells, the lifespan of the data storage unit is rapidly reduced, thereby preventing the product performance and memory efficiency of the vehicle black box device. This has the effect of being improved.

1 is a plan view showing a vehicle black box device according to an embodiment of the present invention.
Figure 2 is a block diagram showing a vehicle black box device according to an embodiment of the present invention.
3 is a flowchart illustrating a method of checking a state of a data storage unit using a vehicle black box apparatus according to an embodiment of the present invention.
Figure 4 is a block diagram showing a vehicle black box device according to another embodiment of the present invention.
5 is a flowchart illustrating a memory management method using a vehicle black box device according to another embodiment of the present invention.

Hereinafter, a vehicle black box apparatus according to the present invention will be described in detail with reference to the accompanying drawings and embodiments. In the drawings, the same reference numerals will be used throughout the specification to omit the parts that are not related to the description in order to clearly illustrate the present invention.

First, a vehicle black box apparatus according to an embodiment of the present invention will be described.

Referring to FIG. 1, a plan view showing a vehicle black box apparatus according to an embodiment of the present invention is shown, and referring to FIG. 2, a block diagram showing a vehicle black box apparatus according to an embodiment of the present invention is provided. 3, a flowchart illustrating a method of checking a state of a data storage unit using a vehicle black box apparatus according to an embodiment of the present invention is illustrated.

As shown in FIG. 1 and FIG. 2, the vehicle black box device 100 according to an embodiment of the present invention may include a key input unit 110, a photographing unit 120, a sensor unit 130, and a data storage unit 140. ), A controller 150, a memory manager 160, a display 170, a voice output unit 180, and a data communication unit 190. The vehicle black box apparatus 100 according to the present invention may record and check the vehicle at all times or in an emergency situation. The vehicle black box apparatus 100 may include a memory manager 160 to record a bad state of the data storage 140. It is possible to prevent the abnormal operation of the vehicle black box device 100 due to the loss of the image data or the failure of the data storage unit 140. Meanwhile, in the configuration of the vehicle black box apparatus 100 of FIG. 2, a part connected by a solid line represents a path through which a driving signal is moved, and a part connected by a dotted line represents a path through which actual data is moved.

First, the key input unit 110 includes a power key 111, a recording control key 112, a defective rate test key 113, and a data transmission key 114 provided on one side of the vehicle black box device 100. do. That is, the key input unit 110 turns on / off the power from the driver, selects a camera to be photographed, controls the recording screen, executes a defect ratio test, and transmits the recorded image data or the data storage unit 140 to the outside. You will be asked to enter. Accordingly, the key input unit 110 outputs the key code corresponding to the key input of the driver to the controller 150 to be described below.

The photographing unit 120 photographs an image around the vehicle through a camera installed at all sides of the vehicle, and transmits the captured image data to the data storage unit 140 under the control of the controller 150.

The sensor unit 130 detects a shock applied to the vehicle through a shock sensor installed on all sides of the vehicle, and outputs the detection signal to the controller 150 to be described below. The controller 150 determines that the image data outputted through the photographing unit 120 is an image data of an emergency situation by inputting a detection signal of the sensor unit 130 and thus impacts the storage area of the data storage unit 140 to be described below. The image data may be controlled to be stored in the image data storage area. On the other hand, when the detection signal is not input, the controller 150 determines the image data as the image data of the usual situation and controls to store the image data in the data storage area of the data storage unit 140 of the time. Meanwhile, in the present invention, the sensor unit 130 may be configured to detect the movement of the vehicle through the acceleration sensor so that the controller 150 may determine the image data of the driving situation according to the driving speed of the vehicle.

The data storage unit 140 stores image data transferred from the photographing unit 120 in a plurality of memory cells. To this end, the memory cells of the data storage unit 140 may be divided to have at least two logical storage areas. One memory may store image data at all times, and the other may store shock image data. The data storage unit 140 transmits the image data to the display unit 170, the audio output unit 180, and the data communication unit 190 to record or describe the image data of the photographing unit 120 under the control of the controller 150. To pass. The data storage unit 140 of the present invention may always check the percentage of the defective memory cells among the plurality of memory cells in conjunction with the memory cell manager 160 to be described below. That is, when the driver inputs the defective rate inspection key 113, the controller 150 inputs a key code corresponding to the defective rate inspection key 113 to perform a memory cell defect inspection through the memory manager 160 to be described below. Run The data storage unit 140 may be formed of a Secure Digital Card (SD Card) configured of a Multi Level Cell (MLC) or a Triple Level Cell (TLC), but is not limited thereto.

The controller 150 inputs a key code corresponding to a key input of each of the power key 111, the recording control key 112, the defective rate inspection key 113, and the data transmission key 114 as a vehicle black box device. The driving of the 100 is controlled. The controller 150 controls the power supply of the vehicle black box apparatus 100 by inputting the key code of the power key 111 and selects a camera to monitor the vehicle by inputting the key code of the recording control key 112. In addition, the recording screen may be controlled, and the memory manager 160 to be described below is driven by inputting the key code of the defective ratio test key 113 to control the state of the data storage 140. In addition, the controller 150 controls the image data stored in the data storage 140 to be transmitted to the data communication unit 190 by inputting the key code of the data transmission key 114. The control unit 150 inputs a key code corresponding to the bad rate test key 113 to output a test signal to the memory manager 160, and from the memory manager 160 to the bad memory cell of the data storage unit 140. The occupancy rate is calculated and the driver is notified of the state of the data storage unit 140 according to the defective rate through the display unit 170, the voice output unit 180, and the data communication unit 190.

The memory manager 160 calculates a ratio of defective memory cells among the plurality of memory cells of the data storage 140 and outputs the state of the data storage 140 according to the defective rate. In more detail, the memory manager 160 includes defective memory cell inspecting units M1 and 161, defective rate calculating units M2 and 162, and boundary signal output units M3 and 163. The bad memory cell inspecting unit 161 detects a bad memory cell by arbitrarily writing and reading test data to the data storage unit 140 using the test signal of the controller 150 as an input. The bad memory cell inspecting unit 161 sequentially checks the addresses of the plurality of memory cells of the data storage unit 140, and if the test data written and the test data read are the same, the memory cells of the next address are checked. If not, the corresponding memory cell is detected as a bad memory cell, and the address of the bad memory cell is recorded. In addition, the bad memory cell inspecting unit 161 may determine whether the memory cell currently being inspected is the last memory cell through the address of the memory cell, and if the writing and reading of the test data of the last memory cell is completed, the bad memory cell is recorded. It counts and outputs a test completion signal including count information of the defective memory cell to the defective rate calculating section 162. The defective rate calculating unit 162 receives the test completion signal as an input, calculates a defective rate occupied by the defective memory cells among all the memory cells of the data storage 140, and outputs the result to the boundary signal output unit 163. The alert signal output unit 163 transmits the state of the data storage unit 140 determined according to the defective rate to the display unit 170, the voice output unit 180, and the data communication unit 190. For example, the boundary signal output unit 163 outputs normal data considering that the data storage unit 140 operates normally when the failure rate is less than 50%, and when the failure rate exceeds 50% and is less than 70%. Attention data is output, and if the defective rate exceeds 70%, it can be designed to output replacement data. The driver may check the state of the data storage unit 140 using a screen and a voice through the display unit 170 and the voice output unit 180, and may transmit data through a terminal wirelessly connected to the data communication unit 190 from outside the vehicle. The state of the storage unit 140 can be checked.

The display unit 170 displays image data recorded in the data storage unit 140 or the state of the data storage unit 140 on the screen under the control of the controller 150. The display unit 170 selectively displays at least one recorded image data on the screen, and displays the state of the data storage unit 140 transmitted from the memory manager 160 on the screen. The display unit 170 may be formed of any one panel selected from LCD, LED, PDP and OLED or touch panel, but is not limited thereto.

The voice output unit 180 may output an operation guidement for driving the vehicle black box apparatus 100 as a voice under the control of the controller 150, and may include a data storage unit received from the memory manager 160. The state of 140 is output by voice.

Finally, the data communication unit 190 transmits the state of the image data and the data storage unit 140 to the terminal (not shown) of the driver connected by the wireless network. The data communication unit 190 inputs a control signal of the controller 150 corresponding to the data transmission key 114 to connect the driver's terminal to transmit the state of the image data and the data storage unit 140. The data communication unit 190 may be connected to the driver's terminal through a wireless environment such as WiFi or Bluetooth. However, the data communication unit 190 is not limited to the wireless environment in which the data communication unit 190 is connected to the driver's terminal.

Although not shown, the vehicle black box apparatus 100 of the present invention may receive power required for driving the key input unit 110 to the data communication unit 190 through a power supply unit (not shown), and the power may be mounted in a vehicle. The battery may be supplied through a battery or an external power supply or an internal battery, but is not limited thereto.

As shown in FIG. 3, the vehicle black box apparatus 100 of the present invention includes a test data write / read step S1, a test data check step S2, a memory cell address increase step S3, and a check completion check step. The state of the data storage unit 140 is inspected through step S4, a defective rate calculation step S5, and a data transmission step S6.

First, the test data writing / reading step (S1) is a step of randomly writing and reading test data by inputting a test signal of the controller 150 from the bad memory cell tester 161. The bad memory cell inspecting unit 161 sequentially writes / reads test data into memory cells corresponding to the first to last addresses of the data storage unit 140, starting with the input of the test signal.

The test data checking step S2 is a step of detecting a defective memory cell according to whether the test data written in the test data writing / reading step S1 and the read test data are the same. The bad memory cell inspecting unit 161 performs the inspection of the next step when the written test data and the read test data are the same, and includes a bad memory cell writing step (S21) when the test data is not the same. In the bad memory cell writing step (S21), the bad memory cells are recorded and the accumulated bad memory cells are counted.

The memory cell address increasing step (S3) is a step of increasing the address of a memory cell to be examined for sequential inspection of a plurality of memory cells. The bad memory cell inspecting unit 161 searches for the memory cell whose address is increased by one step from the examined memory cell by referring to the memory cell address of the data storage unit 140.

The inspection completion confirmation step (S4) is a step of confirming whether the address of the examined memory cell is a final address. The bad memory cell inspecting unit 161 transmits a test completion signal including count information of the bad memory cell recorded in the bad memory cell writing step S21 to the bad rate calculating unit 162 when the address of the tested memory cell is the last address. Output

The defective rate calculating step (S5) is a step of calculating the defective rate of the memory cell based on the count information of the defective memory cell. The defective rate calculating unit 162 receives the test completion signal as an input, calculates the defective rate occupied by the defective memory cells among all the memory cells, and outputs the result to the boundary signal output unit 163.

Finally, the data transmission step S6 is a step of transmitting the state of the data storage unit 140 corresponding to the defective rate of the memory cell. The alert signal output unit 163 simultaneously or selectively transmits the state of the data storage unit 140 determined according to the defective rate to the display unit 170, the voice output unit 180, and the data communication unit 190. As described above, the boundary signal output unit 163 outputs the state of the data storage unit 140 classified into normal, caution, and replacement data according to the defective rate, so that the driver can efficiently manage the data storage unit 140. Help

Vehicle black box device 100 of the present invention described above before the parking or driving in the state in which the driver boarded the vehicle The memory manager 160 may be driven to immediately recognize the state of the data storage 140. In addition, since the state of the data storage unit 140 can be checked through a driver's terminal such as a smartphone even outside of the vehicle, anxiety about failure of the data storage unit 140 can be normally resolved, and the data storage unit 140 can be used. In accordance with the state of the data storage unit 140 by immediately replacing the timely use, the vehicle black box device 100 can be used stably.

Next, a vehicle black box apparatus according to another embodiment of the present invention will be described.

Referring to FIG. 4, there is shown a vehicle black box apparatus according to another embodiment of the present invention. Referring to FIG. 5, a flow illustrating a memory management method using the vehicle black box apparatus according to another embodiment of the present invention. The chart is shown.

As shown in FIG. 4, the vehicle black box apparatus 200 according to another embodiment of the present invention may include a key input unit 210, a photographing unit 220, a sensor unit 230, a data storage unit 240, and a controller. 250, a memory manager 260, a display 270, a voice output unit 280, and a data communication unit 290. In other embodiments of the present invention, the rest of the configuration except for the data storage unit 240 is the same as that of the embodiment of FIGS. 1 to 3, and the following description will focus on differences from the embodiment of FIGS. 1 to 3. do.

The data storage unit 240 according to another embodiment of the present invention rearranges the logical storage areas of the entire memory cells according to the frequency of use of the memory cells. In more detail, the data storage unit 240 includes alarm units DS1 and 241, storage area rearrangement units DS2 and 242, and capacity comparison units DS3 and 243. The alarm unit 241 counts the frequency of use of the current memory cell arranged as the storage area of the image data and designates an unused memory cell according to the frequency of use. That is, the alarm unit 241 designates the memory cell to be used as the unused memory cell and outputs an unused memory cell confirmation signal when the frequency of use of the memory cell to be used is counted higher than a predetermined level. Here, a criterion of a certain level, that is, a use frequency, which is a classification criterion of unused memory cells is determined by the configuration of the memory cells. For example, when the memory cells of the data storage unit 240 are configured as MLCs, the frequency of use as the classification criteria of the unused memory cells may be set to 500, which is 1/10 of the reference frequency. In addition, when the memory cell of the data storage unit 240 is configured as a triple level cell (TLC), the frequency of use as the classification criteria of the unused memory cells may be set to 100 times that is 1/10 of the reference frequency. Although the present invention does not limit the number of times of a predetermined level that is a classification criterion of the unused memory cell, the description will be made by setting the initial frequency of use as the classification criterion of the unused memory cell to 100 times for convenience of description. For example, when the frequency of use of the memory cell to be used is counted as 101 times, the alarm unit 241 outputs an unused memory cell confirmation signal to the storage area relocating unit 242 which designates the memory cell to be used as an unused memory cell.

The storage area relocator 242 relocates the storage area of the data storage 240 by inputting an unused memory cell confirmation signal. That is, the storage area relocator 242 designates the remaining memory cells except the unused memory cells designated by the alarm unit 241 among all the memory cells as the storage area of the image data. Therefore, memory cells used more than 101 times no longer store data until rearranged to the storage area of the image data.

The capacity comparison unit 243 compares the total capacity of the memory cell being used with the capacity of the initial data storage unit 240. The capacity comparison unit 243 outputs a memory cell capacity comparison signal to the storage area rearrangement unit 242 when the total capacity except the unused memory cell corresponds to half of the capacity of the first data storage unit 240. Accordingly, the storage area relocator 242 allows the unused memory cells to be relocated to be used as storage areas of the image data.

On the other hand, the alarm unit 241 may set the frequency of use as a reference 200 times higher than 100 when the memory cell to be used currently includes a previously designated unused memory cell. The alarm unit 241 may designate the unused memory cell and at the same time record the address information of the unused memory cell to know the information on the previously designated unused memory cell. Accordingly, when the frequency of use of the memory cell to be used is counted higher than 200 times, the alarm unit 241 designates the memory cell to be used as the unused memory cell and simultaneously stores the unused memory cell confirmation signal in the storage area relocating unit 242. Will output

As shown in FIG. 5, the vehicle black box device 200 according to another exemplary embodiment of the present invention may include a memory cell frequency counting step S100, a storage area rearrangement step S200, a storage capacity comparison step S300, and the like. The life span of the data storage unit 140 may be increased by efficiently managing the storage area of the image data through the storage area expansion rearrangement step S400 and the frequency of use criteria change step S500.

The memory cell frequency counting step (S100) is a step of counting the frequency of use of the current memory cell arranged as a storage area of the image data. The alarm unit 241 counts the frequency of use of the memory cell to be used, which is arranged as a storage area of the image data through the control unit 250, and when the frequency of use is higher than the first level (100 times), the memory cell to be used is not used. An unused memory cell confirmation signal designated as a memory cell is outputted to the storage area rearrangement unit 242. In addition, the alarm unit 241 records the address information of the unused Merolicell designated for the application of the frequency of use change step (S500).

The storage area rearrangement step (S200) is a step of rearranging the remaining memory cells except the unused memory cells from all the memory cells to the storage area of the image data. That is, the storage area relocator 242 relocates the memory cell to be used currently by inputting an unused memory cell confirmation signal of the alarm unit 241.

In the storage capacity comparison step (S300), when the frequency of use of the relocated memory cells increases and the capacity of the unused memory cells increases, the capacity of the used memory cells and the unused memory cells for efficient management of the data storage unit 240 is determined. Comparing step. If the capacity of the first data storage unit 240 is 1 GB, the capacity comparison unit 243 outputs a memory cell capacity comparison signal to the storage area rearranging unit 242 when the capacity of all memory cells currently being used becomes 500 MB.

The storage area enlargement arrangement step (S400) is a step of expanding and arranging a storage area of the image data to include an unused memory cell in a currently used memory cell. The storage area relocating unit 242 relocates the storage area of the image data including all unused memory cells designated by the alarm unit 241 by inputting the memory cell capacity comparison signal, so that the capacity of the memory cell to be used as the storage area is 1GB. Is initialized to

The use frequency reference changing step (S500) is a step of changing and applying a frequency of use, which is a reference for designating unused memory cells, to a second level (for example, 200 times). The alarm unit 241 may determine whether the memory cell to be currently used is a previously designated unused memory cell based on the address information of the unused memory cell recorded in the memory cell frequency counting step S100. Therefore, the alarm unit 241 may designate the unused memory cell again by setting the frequency of use of the unused memory cell to the second level (200 times) higher than the first level (100 times).

Meanwhile, the vehicle black box apparatus 200 of the present invention designates an unused memory cell based on the frequency of use of the N-th level, which is a higher number of times from the third level (for example, 300 times) and image data in the same manner as above. Can be made to be relocated. In addition, when there are unused memory cells in which the frequency of use is over 70% of the life span in the storage area enlargement arrangement step (S400), only the remaining memory cells except for the unused memory cells are used. The region may be rearranged but is not limited in this invention.

In the vehicle black box apparatus 200 according to another exemplary embodiment of the present invention, the alarm unit 241 designates an unused memory cell according to the frequency of use of the memory cell, and excludes the unused memory cell from the storage area relocator 242. In addition, by relocating a storage area of logically divided image data, all memory cells of the data storage unit 240 may be efficiently used. In addition, the vehicle black box apparatus 200 further includes a capacity comparing unit 243 to check the capacity of the unused memory cells in comparison with the capacity of the memory cells currently being used, and then rearrange the storage areas of the entire memory cells to display the image data. Secure the capacity of the data storage unit 240 for storage. Accordingly, the present invention provides a vehicle black box apparatus 200 in which the lifespan of the data storage unit 240 is rapidly reduced, thereby improving product performance and memory efficiency.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims and their equivalents. It is to be understood that such changes are within the scope of the claims.

100, 200: vehicle black box device 110, 210: key input unit
111: power key 112: recording control key
113: Bad rate test key 114: Data transfer key
120, 220: photographing unit 130, 230: sensor
140, 240: data storage unit 241: alarm unit
242: storage relocation unit 243: capacity comparison unit
150: control unit 160: memory management unit
161: bad memory cell inspection unit 162: bad ratio calculation unit
163: boundary signal output unit 170: display unit
180: audio output unit 190: data communication unit

Claims (5)

A key input unit for outputting a key code according to a driver's key input, a photographing unit for outputting image data photographed through a camera installed in at least one of front, rear, and side directions of the vehicle, and a shock applied to the vehicle A vehicle black box apparatus comprising: a sensor unit configured to detect and output a detection signal; and a data storage unit having a plurality of memory cells divided into at least two logical storage areas.
The operation of the camera is controlled by inputting the key code, and the image data is selectively stored in the storage areas of the plurality of memory cells by determining whether the recording state of the photographing unit is always or emergency based on the detection signal. A control unit for controlling the data to be stored and outputting a test signal for checking a state of the data storage unit using the key code as an input, and calculating a ratio of the defective memory cell among the plurality of memory cells by inputting the test signal. A memory manager which outputs a state of the data storage unit corresponding to the defective rate, a display unit which displays the state of the image data and the data storage unit on the screen according to a control signal of the controller, and a control signal of the controller. The voice output unit and the control unit outputting the state of the data storage unit as voice. A; by the control terminal of the driver data communication unit for transmitting the condition data or the image data storage unit
Vehicle black box device, characterized in that it further comprises.
The method according to claim 1,
The memory management unit,
The test signal of the controller is input, the test data is sequentially written according to the addresses of the plurality of memory cells, and the test data is read to detect the bad memory cell and write the address of the bad memory cell. A bad memory cell inspecting unit outputting a test completion signal when the memory cell of the last address is inspected;
A defective rate calculating unit configured to calculate the defective rate occupied by the defective memory cell among all the memory cells of the data storage unit by inputting the test completion signal; And
If the defective rate inputted through the defective rate calculation unit is less than 50%, normal data is output; if more than 50% and less than 70%, caution data is output; if defective rate is more than 70%, replacement data Vehicle signal box comprising a; outputs a boundary signal output unit.
3. The method according to claim 1 or 2,
The data storage unit stores,
Count the frequency of use of the memory cell to be used currently arranged as the storage area of the image data, and if the frequency of use of the memory cell to be used is counted higher than the first level, unused to designate the memory cell to be used as an unused memory cell. An alarm unit for outputting a memory cell confirmation signal; And
And a storage area rearranging unit configured to designate the remaining memory cells of the plurality of memory cells except the unused memory cells as the storage area of the image data by using the unused memory cell confirmation signal as an input. Box device.
3. The method of claim 2,
The bad memory cell inspecting unit sequentially checks each address of the plurality of memory cells, and if the written test data and the read test data are the same, checks the memory cell of the next address. Detecting a bad memory cell and recording an address of the bad memory cell.
The method of claim 3, wherein
The data storage unit stores,
And a capacity comparator for outputting a memory cell capacity comparison signal when the total capacity of the currently used memory cells rearranged through the storage area relocation unit corresponds to half of the initial capacity of the data storage unit.
The storage area relocating unit reassigns the storage area of the image data including the unused memory cell to the memory cell being used by inputting the memory cell capacity comparison signal.
And the alarm unit designates an unused memory cell based on a second level higher than the first level when the memory cell to be used currently includes a previously designated unused memory cell.

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