JP4768541B2 - Driving information recording device - Google Patents

Description

  The present invention relates to a driving information recording apparatus that circulates and stores driving information related to vehicle driving.

  The conventional driving information recording device cyclically records driving information related to vehicle driving, and when there is a dangerous driving or the like, the driving information recording device uses the triggered driving information as a trigger. An apparatus for recording on a recording medium is disclosed. In such an apparatus, since a plurality of driving information is recorded seamlessly (endlessly), information before dangerous driving can also be recorded (see, for example, Patent Document 1).

JP 2000-6854 A

  In order to simplify the configuration of the conventional operation information recording apparatus, only the minimum necessary notification means and the minimum necessary operation buttons such as a recording start button for recording the operation information on the recording medium are provided. Not. Since the configuration of the driving information recording device is simplified in this way, various settings of the driving information recording device, for example, time adjustment and initial value setting such as a gravity sensor cannot be performed using operation buttons or the like. There's a problem. If the time cannot be adjusted, the time when the driving information is recorded is not accurate if the time is shifted, and the reliability of the recorded driving information is lowered. If the initial value of the gravity sensor cannot be set, dangerous driving may be undesirably detected, so that driving information may not be recorded at an appropriate timing.

  In order to solve such a problem, it is conceivable to connect an information processing device capable of operating the driving information recording device to the driving information recording device, but it is necessary to connect the information processing device only for setting. So work efficiency is bad.

  Therefore, an object of the present invention is to provide a driving information processing apparatus that can easily set predetermined items even with a simple configuration.

The present invention (1) is a driving information recording apparatus that circulates and stores driving information related to vehicle driving in a storage means, and records the driving information stored in the storage means on a recording medium.
Acceleration detecting means for detecting the acceleration of the vehicle;
By the first operation, command information for instructing an operation for writing the operation information stored in the storage means to the recording medium, and specific information based on a predetermined second operation different from the first operation are input. Input means;
Determining means for determining whether the information input by the input means is the specific information;
When the determination means determines that the information input by the input means is the specific information, the value detected by the acceleration detection means is set as an initial value for correcting the offset of the acceleration detection means. Setting means;
It is the driving information recording device characterized by comprising.

According to the present invention (1), when the setting means determines that the information input by the input means is the specific information, the setting means sets the value detected by the acceleration detection means as the offset of the acceleration detection means. It is set as corrected by the initial value. Therefore, the input means is originally means for inputting command information for instructing the writing operation, but if the information input by the input means is specific information, the offset of the acceleration detection means is corrected as described above. The initial value is set. As a result, the initial value for correcting the offset of the acceleration detecting means can be set using the input means. Therefore, in order to simplify the configuration of the driving information processing apparatus, the initial value can be easily set using the input means without providing a dedicated means for setting the initial value for correcting the offset of the acceleration detecting means. can do. This improves convenience.

  Hereinafter, a plurality of embodiments for carrying out the present invention will be described with reference to the drawings. Portions corresponding to the matters described in the preceding forms in each embodiment are denoted by the same reference numerals, and overlapping description may be omitted. When only a part of the configuration is described, the other parts of the configuration are the same as those described in the preceding section. Not only the combination of the parts specifically described in each embodiment, but also the embodiments can be partially combined as long as the combination does not hinder.

  FIG. 1 is a perspective view showing the relationship between the drive recorder 1 and the control device 2 according to the first embodiment of the present invention. FIG. 2 is a perspective view of a modified form in which the drive recorder 1 is partially changed. FIG. 3 is a diagram for explaining a camera mounting position on the vehicle 3. 4 is a diagram showing the center 4, FIG. 4 (a) is a diagram showing a center device configuration, and FIG. 4 (b) is a diagram showing a travel locus, a captured image, an imaging time, and a G of the vehicle 3 on the display 4a. It is a figure showing the one aspect | mode which output the sensor measurement value. In the first embodiment, the drive recorder 1 is provided by being electrically connected to an operation management control device 2 (sometimes referred to as an AVM-ECU 2) mounted in advance on the vehicle 3. For example, the position, time and dynamic information of the vehicle 3 can be transmitted from the control device 2 to the center 4 using a digital radio frequency in the 400 MHz band, and the center 4 can transmit a plurality of vehicles 3 based on the information. Of these, instructions are given to specific vehicles. Further, the center 4 issues an image photographing request to the drive recorder 1 via the control device 2 using the radio frequency or the like. However, the applied radio frequency is not necessarily limited to the 400 MHz band. For example, a frequency band allocated for a mobile phone may be applied. An analog radio frequency may be applied instead of a digital radio frequency.

  A drive recorder 1 (sometimes referred to as a first drive recorder 1) serving as an operation information recording apparatus according to the first embodiment includes the position, time and dynamic information of the vehicle 3 from the control device 2 (these are referred to as information and the like). And, when a predetermined condition is satisfied, the image and audio information are recorded in association with the information or the like. The center device is configured to be able to analyze and output these pieces of information recorded in the first drive recorder 1.

  The first drive recorder 1 includes a drive recorder main body 5 (sometimes referred to as a drive recorder main body 5), a camera 6 that is an image pickup means, a microphone 7 that is a sound information acquisition means for acquiring sound information in the passenger compartment, and an information output that outputs warning information. It has a buzzer 8 as means. The camera 6 and the microphone 7 are electrically connected to the drive recorder body 5 and provided separately, and the buzzer 8 is provided integrally with the drive record body 5. The vehicle 3 is provided with at least one camera 6.

  The camera 6 is realized by a CCD camera (CCD: Charge Coupled Device). This camera 6 is affixed to a windshield 3a, for example, on the back of the rearview mirror via a bracket (not shown) so as to photograph the vehicle front direction indicated by the arrow D1 in FIG. That is, the camera 6 is fixed toward the front of the vehicle. In the first draco 1, as an option, a second or third camera 6 can be provided in the vehicle 3. Specifically, the camera 6 </ b> A for photographing inside the passenger compartment 3 or photographing behind the vehicle. It is also possible to provide a camera 6B. There may be a case where the photographing switch 9 for photographing these cameras 6 is electrically connected to the dorareco body 5 and provided separately.

Further, as shown in FIG. 2, the GPS (GPS: Global:
Positioning System) A drive recorder 1A to which an antenna 10 and a GPS receiver (not shown) are added can also be applied to a vehicle.

FIG. 5 is a perspective view of the drive recorder 1, and FIG. 6 is a front view of the drive recorder 1. A CF card (CF: Compact Flash) 11 serving as a recording medium can be inserted into and removed from the dorareko body 5. The CF card 11 has a structure in which a flash memory that does not lose its memory even when it is not energized, and a controller circuit that is responsible for input / output to / from the outside are combined into a single card. A first RAM (RAM: later described) of the dorareko main body 5.
Random Access Memory) 12 sequentially records the vehicle periphery image, audio information from the microphone in the vehicle interior, driving information including position, individual and time in an endless manner. When predetermined conditions are satisfied, at least a part of these pieces of information is recorded on the CF card 11.

FIG. 7 is a block diagram showing the electrical configuration of the drive recorder 1, the control device 2, and the center 4. FIG. 8 is a block diagram showing an electrical configuration of the drive recorder 1. FIG. 9 is a block diagram illustrating an electrical configuration of the control device 2. The drive recorder body 5 includes a first CPU (CPU: Central Processing Unit) 13 as control means and a first ROM (ROM: Read).
Only Memory (14), the first RAM 12 as a storage means, a CF card interface 15, a JPEG IC (JPEG: Joint Photographic coding Experts Group, IC: Integrated Circuit) 16, a video switch 17, a light emitting diode (abbreviated LED) : Light Emitting Diode, see FIG. 5) 18 and a memory switch 60 as input means. The drive unit 5 includes a USB HOST (USB: Universal Serial Bus) 19 that is a means having a USB host function, a USB interface 20, a first communication driver 21 that exchanges information with the control device 2, An LCD controller connector (LCD: Liquid Crystal Display) 22, a first buffer 23, a first circuit 24 for detecting a power activation signal from the control device 2, a first watchdog IC 25 having a watchdog function, 1 further includes a power supply unit 26, a G sensor 27 serving as acceleration detection means, and a counter (not shown) that counts vehicle speed pulses. The LCD operation unit connector 22 is configured to be connectable to an LCD operation unit 28 for maintenance mode, which will be described later.

  The G sensor 27 is a sensor that detects a gravitational acceleration so-called G sensor output value that acts in the longitudinal direction, the lateral direction, and the vertical direction of the vehicle 3. The front direction and the rear side of the driver seated on the driver's seat of the vehicle 3 are defined as the front-rear direction, and the left and right directions of the driver seated on the vehicle 3 are defined as the left-right direction. The direction orthogonal to the front-rear and left-right directions is the up-down direction. The front-rear direction is defined as the Y-axis direction, and the left-right direction is defined as the X-axis direction. The G sensor output value in the X-axis direction, the G sensor output value in the Y-axis direction, and the G sensor output value in the Z-axis direction are detected and recorded independently. As described above, since the G sensor 27 can detect the output values of the triaxial G sensors, it is possible to improve the degree of freedom of attachment such as vertical installation and horizontal installation when the G sensor 27 is attached to the vehicle 3.

  The memory switch 60 can input command information for instructing an operation for writing the operation information stored in the first RAM 12 to the CF card 11. Further, the memory switch 60 can correct the offset in the front-rear direction, the left-right direction, and the up-down direction of the G sensor 27 by performing a predetermined operation.

  The first RAM 12 includes a first SD-RAM 29 (SD-RAM: Synchronous DRAM) and a second SD-RAM 30, and the first SD-RAM 29 temporarily records a raw image taken by a camera. The recorded image is converted into JPEG format image data. The second SD-RAM 30 is configured to record endlessly and cyclically the image data converted into the JPEG format, the G sensor output value from the G sensor 27, the sound, and the like.

  The first ROM 13, the second SD-RAM 30, and the CF card interface 15 are electrically connected to the first CPU 13, respectively, and the first SD-RAM 29 and the video switch 17 are electrically connected to the first CPU 13 via the JPEG IC 16. Has been. The video switch 17 is a change-over switch for switching between the cameras 6 and 6A (6B) that capture images at predetermined time intervals when a plurality of cameras 6 and 6A (6B) are provided.

  A USB interface 20 is electrically connected to the first CPU 13 via a USB HOST 19, and a communication driver 21, an LCD operation device connector 22, a first buffer 23, a first watchdog IC 25, a G sensor 27, and a memory switch 60 are electrically connected to each other. The first buffer 23 is electrically connected to the first circuit 24. A first power supply unit 26 is electrically connected to the first watchdog IC 25.

  The first CPU 13 also has a function as a determination unit, and determines whether or not the command information input by the memory switch 60 is predetermined specific information. The command information is information given by operating the memory switch 60 by a normal switch, and is information based on a predetermined number of times, for example, one operation within a predetermined time, for example, 1 second. The specific information is information given by operating the memory switch 60 as a special switch that is not normal, and is information based on a predetermined number of times, for example, twice during a predetermined time, for example, 1 second. is there. Further, for example, the specific information is information based on the operation of the memory switch 60 continuously for a predetermined time, for example, 5 seconds. Therefore, the first CPU 13 can determine whether the command information given from the memory switch 60 is specific information.

  Further, the first CPU 13 has a function as setting means, and when the command information given from the memory switch 60 is determined to be the specific information, the first CPU 13 sets the value detected by the G sensor 27 to a predetermined initial value. In the present embodiment, there can be a situation in which the drive recorder body 5 incorporating the G sensor 27 cannot be installed completely horizontally, so that the memory switch 60 is operated in a special manner as described above, so that The horizontal and vertical offsets are corrected. When the vehicle 3 travels on a rough road, the vertical vibration is undesirably increased, and it is expected that the G sensor 27 detects gravitational acceleration in the front-rear and left-right directions. Accordingly, the G sensor output value can be subjected to processing for observing vertical vibrations on rough roads and reducing erroneous reactions.

  The first CPU 13 is configured to start up the first power supply unit 26 that is the main power supply based on the power-on information from the control device 2. When the power activation signal cannot be obtained from the control device 2, the input from the communication driver 21 is switched to the input to the GPS antenna side by a switch, assuming that the control device 2 is not connected. Thus, the position from the GPS can be detected alone instead of the position information from the control device 2.

  The control device 2 includes a microcomputer including a second CPU 31 for AVM, a second ROM 32 and a second RAM 33, a second buffer 34, a GPS receiver 35, a GPS antenna 36, an ASIC 37 (ASIC: Application Specific Integrated Circuit), a first 2 includes a communication driver 38, an LCD controller 39, a second watchdog IC 42, and a second power supply unit 43. A second ROM 32 and a second RAM 33 are electrically connected to the second CPU 31, and a card M conforming to the PCMCIA standard is electrically connected via the second buffer 34. A second communication driver 38 is electrically connected to the second CPU 31 via the ASIC 37, and a digital radio 45 capable of transmitting and receiving at a digital radio frequency of 400 MHz band is electrically connected to the second communication driver 38. ing. By the way, in 1st Embodiment, although the GPS receiver 35 and the GPS antenna 36 are provided in the control apparatus 2, as shown in FIG. 2, the structure in which the GPS receiver and the GPS antenna 10 are provided in the dorareko main body 5 is shown. It is also possible to make it.

  When the LCD controller 28 is connected to the LCD operator connector 22, the drive recorder body 5 shifts from the normal mode to a maintenance mode for setting and inspecting the drive recorder body 5. Various settings can be changed by connecting the LCD controller 28.

  The position information and time information are acquired using the GPS antenna 36 and the GPS receiver 35. Driver data can be input from the LCD controller 39. The position information and time information are temporarily stored in the second RAM 33. When there is a request for information transmission from the center 4 via the digital wireless device 45, the information stored in the second RAM 33 is transmitted to the center 4 via the digital wireless device 45. Moreover, the control apparatus 2 may transmit to the center 4 voluntarily regularly. Further, when there is an instruction from the center 4 via the digital wireless device 45, the control device 2 notifies the driver via the speaker SP.

  Since the control device 2 originally has such a basic function, the control device 2 transmits the obtained position information and time information to the drive recorder 1 via the driver 38 via the serial communication line SL. . The drive recorder 1 receives the information via the first communication driver 21 and stores it in the second SD-RAM 30.

  FIG. 10 is a block diagram illustrating an electrical configuration of a main part of the control device 2. FIG. 11 is a block diagram showing an electrical configuration of a main part of the drive recorder 1. FIG. 12 is a diagram for explaining a delay circuit for resetting by hardware when the watchdog pulse is stopped or does not operate at a predetermined cycle. As shown in FIG. 10, in the control device 2, the accessory power source of the vehicle 3 is connected to the input side 46 a of the OR circuit 46, that is, the OR circuit 46, and the second CPU 31 controls the other input side 46 b of the OR circuit 46. A signal is supplied. A power-on signal S1 is supplied from the second power supply unit 43 connected between the OR circuit 46 and the second CPU 31 to the drive recorder 1 side. That is, as shown in FIG. 11, in the drive recorder 1, an accessory power supply is connected to one input side 47a of the OR circuit 47, and the power-on signal S1 is supplied to the other input side 47b of the OR circuit 47.

  The drive recorder 1 is activated when the ACC signal supplied from the accessory power supply is turned on or the control device 2 is turned on. Further, the drive recorder 1 performs termination control by software so that data recording can be performed even when the ACC signal is off and the second power supply unit 43 of the control device 2 is off (falling signal in FIG. 12). It is like that. As shown in FIG. 12, when a watchdog pulse (denoted as a WD pulse in FIG. 12) is generated by software during operation of the control device 2 and the watchdog pulse is stopped or does not operate at a specified cycle, A reset is applied. In the present embodiment, the second watchdog IC 42 and the second CPU 31 correspond to a delay circuit.

  FIG. 13 is a block diagram illustrating an electrical configuration of a main part according to a modified form in which the drive recorder 1 is partially changed. In the present embodiment, the ACC signal and the power-on signal S1 are supplied to the input side of the OR circuit 47 in the drive recorder 1, but the present invention is not necessarily limited to this form. That is, as shown in FIG. 13, the drive recorder 1 may be configured such that the ACC signal, the power-on signal, and the control signal S <b> 2 from the first CPU 13 are supplied to the input side of the OR circuit 47. Even in this modified form, when a watchdog pulse is generated by software during operation of the drive recorder 1 and the watchdog pulse is stopped or does not operate at a predetermined cycle, it can be reset by hardware. In the modified form, the first watchdog IC 25 and the first CPU 13 correspond to a delay circuit.

  FIG. 14 is a diagram illustrating a relationship between part of image information and position information. FIG. 15 is a diagram illustrating a mode in which still image information is recorded on the CF card 11 at regular intervals δ based on the G sensor output value. The first CPU 13 converts the input image picked up by the camera 6 and input to the drive recorder body 5 into a JPEG converted image by the JPEG IC 16, and then the first CPU 13 sequentially records the JPEG converted image in the second SD-RAM 30 in an endless manner. . At this time, one still image is recorded in the format of “image * .jpg”, for example. However, the “*” is an integer. As additional information of the recorded still image, the G sensor output value, the position, the time and the vehicle speed information from the vehicle speed sensor 50 of the vehicle 3 and the sound information from the microphone 7 are endlessly stored in the second SD-RAM 30. Record sequentially.

  When the predetermined recording condition is satisfied, the first CPU 13 causes the buzzer 8 to output a recording start signal. At the same time, the first CPU 13 causes the CF card 11 to record the JPEG converted image, G sensor output value, position, time, and vehicle speed information from the vehicle speed sensor 50 recorded in the second SD-RAM 30. In the present embodiment, for example, 10 still images are recorded per second, and 300 still images can be recorded on the CF card 11 per event for a maximum of 30 seconds. One event is synonymous with one state that satisfies a predetermined recording condition.

  The recording conditions will be described. FIG. 16 is a diagram illustrating the relationship between the G sensor output value 48 that exceeds the threshold and the recording range Rh of the image information recorded on the CF card 11. As a recording condition, the G sensor output value 48 is a threshold value Gmax. Or Gmin. Exceeding the threshold value, the JPEG converted image, its G sensor output value, position, time, and vehicle speed information recorded endlessly in the second SD-RAM over the recording range of up to 30 seconds with reference to the time when the threshold is exceeded, and the microphone 7 Is recorded on the CF card 11. The time when the threshold is exceeded may be referred to as a trigger occurrence. The time obtained by adding the recording time Taft seconds after the occurrence of the trigger to the recording time Tbef seconds before the occurrence of the trigger corresponds to the total time of the recording range in one event. A maximum of 30 seconds can be set in a range of 5 seconds to 25 seconds before the trigger occurrence and 5 seconds to 25 seconds after the trigger occurrence.

  As a recording condition, for example, the G sensor output value 48 is a threshold value Gmax. Or Gmin. When the speed of the vehicle 3, that is, the change in the vehicle speed exceeds a predetermined value, the driving information as described above may be recorded on the basis of the threshold excess point. For example, in the case of a large vehicle such as a truck, the G sensor output value 48 greatly fluctuates based on the weight even when the vehicle 3 is safely operated. By combining the output value 48 and the change in the vehicle speed, the recording range can be specified reliably.

  FIG. 17 is a diagram for explaining a threshold determination method for the G sensor output value. This will be described with reference to FIGS. The first CPU 13 acquires the output of the G sensor and determines whether or not the threshold value Gbe has been exceeded. As described above, the G sensor 27 is a three-axis type in the X, Y, and Z axis directions, and is configured to be able to detect the gravitational acceleration in the longitudinal direction, the lateral direction, and the vertical direction of the vehicle 3. Therefore, not only the longitudinal collision accident but also the lateral collision accident can be reliably detected, and the cause can be analyzed. The threshold determination is performed by the vector sum of the gravitational acceleration in the front-rear direction and the gravitational acceleration in the left-right direction. This threshold value can be changed to an arbitrary value by setting.

  FIG. 18 is a diagram illustrating the relationship between the ON signal S3 of the photographing switch 9 and the recording range Rh of the image information recorded on the CF card 11. As a recording condition, when the driver turns on the photographing switch 9 and switches the switching mode, the second SD- is recorded over a recording range of up to 30 seconds on the basis of the photographing switch-on time TR1 (referred to as trigger occurrence). The JPEG converted image recorded endlessly in the RAM 30, the G sensor output value, the position, time and vehicle speed information at the time when the photographing switch is turned on, and the audio information from the microphone 7 are recorded in the CF card 11. The time (Tbef + Taft seconds) obtained by adding the recording time Taft seconds after the occurrence of the trigger to the recording time Tbef seconds before the occurrence of the trigger corresponds to the total time of the recording range in one event. However, when a JPEG converted image or the like is recorded on the CF card 11 using the shooting switch 9 as a trigger, the number of switch operations is limited, and when the predetermined number of operations is reached, the CF card 11 is operated even if the shooting switch 9 is operated thereafter. It is also possible to set the drive recorder body 5 so as not to record.

  FIG. 19 is a diagram illustrating the relationship between the reception of a shooting request command through communication and the recording range Rh of image information recorded on the CF card 11. This will be described with reference to FIG. As a recording condition, if there is a radio frequency image capturing request from the center 4 to the control device 2, the first CPU 13 of the drive recorder body 5 receives the signal as a command. Then, a JPEG conversion image recorded endlessly in the second SD-RAM 30 over a recording range of up to 30 seconds with reference to TR2 (referred to as trigger occurrence) at the time of command reception, the G sensor output value at the time of command reception, The position, time and vehicle speed information and the voice information from the microphone 7 are recorded on the CF card 11. The time (Tbef + Taft seconds) obtained by adding the recording time Taft seconds after the occurrence of the trigger to the recording time Tbef seconds before the occurrence of the trigger corresponds to the total time of the recording range in one event. For example, when the center 4 determines that the speed of the vehicle 3 obtained based on a vehicle speed pulse that is one of the operation data is higher than a predetermined speed, an image recording request from the center 4 is executed. . The parameter resulting from the generation of the trigger is not limited to the vehicle speed pulse. For example, an image recording request may be executed from the center 4 based on operation data of at least one of periodic recording, sudden acceleration, sudden deceleration, and sudden handle. By using the plurality of operation data, it is possible to perform detailed driving guidance for the individual driver at the center 4.

  FIG. 20 is a block diagram for explaining various trigger acquisitions in the drive recorder 1. The trigger input is the G sensor 27, the center 4, the photographing switch 9, and the external switch 49. Information from the control device 2 is periodically transmitted, and is periodically monitored on the time axis. However, in communication, it becomes a trigger as an interrupt. That is, the trigger from the center 4 is an interrupt. An external switch 49 input can input an on / off signal of another switch. Further, an on / off signal of the photographing switch (forced switch by the driver) may be adopted as the external switch input. The external switch input can detect both triggers and conditions.

  FIG. 21 is a diagram illustrating a mode in which warning information is issued based on a threshold of operation data. When the first CPU 13 detects an abnormal operation of the vehicle 3 based on the operation data of at least one of the speed, fixed-cycle recording, sudden acceleration, sudden deceleration, and sudden handle of the vehicle 3, the buzzer 8 warns the driver. Notify information. After the warning information is notified, a warning is given every 30 seconds while the abnormal operation continues. A criterion for determining whether or not the vehicle is in abnormal operation is designated in advance using the CF card 11. As shown in FIG. 21, the upper limit E1 and lower limit E2 of the abnormality detection threshold and the abnormality determination time Te are defined as parameters. When the upper limit is exceeded for a predetermined “abnormality determination time” or more, it is determined that the operation is abnormal. In the present embodiment, the warning information is notified by the buzzer 8, but the present invention is not limited to this. A speaker SP (see FIG. 7) is provided as an information output means in the control device 2 or the first drive recorder 1, and voice synthesis output (for example, “exceeding the specified speed. Please decelerate”) is output from the speaker SP. (Composite output) is also possible.

  A case where abnormal operation is detected based on sudden acceleration and sudden deceleration will be described. The first CPU 13 acquires the speed of the vehicle 3, that is, the vehicle speed by a vehicle speed pulse every 0.1 second, for example, and makes a determination based on an acceleration of 1 second. When the acceleration exceeds the determination value, the first CPU 13 notifies the driver of warning information by the buzzer 8 and records the acceleration on the CF card 11. The first CPU 13 determines “rapid acceleration” when the acceleration is greater than or equal to the specified acceleration, and determines “rapid deceleration” when the acceleration is greater than or equal to the specified deceleration.

  A case where abnormal operation is detected due to overspeed will be described. The first CPU 13 obtains the vehicle speed by a vehicle speed pulse every 0.1 second, for example, and notifies the driver of warning information by the buzzer 8 when the specified speed over determination speed is exceeded and the specified warning start time has elapsed. To do. When the vehicle speed exceeds the prescribed speed over determination speed and the abnormality determination time Te has elapsed, warning information is notified by the buzzer 8 and the vehicle speed 3 is recorded in the CF card 11. When the vehicle speed is equal to or less than the overspeed determination speed, but the road classification of the general road or the highway is changed from one to the other, the overspeed is canceled. Two types of determination speed and warning start time can be set for each road segment.

  FIG. 22 is a diagram illustrating the relationship between the G sensor output value and the detection time. FIG. 23 is a chart showing a tendency based on the relationship between the magnitude of the G sensor output value and its detection time. When the first CPU 13 does not have the necessary and sufficient free space for the recording capacity of the CF card 11 and the G sensor output value already recorded on the CF card 11 is smaller than the newly detected G sensor output value, the first CPU 13 Control is performed to erase the sensor output value and record the detected G sensor output value on the CF card 11. If the free space of the recording capacity of the CF card 11 is necessary and sufficient, even if the G sensor output value already recorded on the CF card 11 is smaller than the newly detected G sensor output value, the already recorded G The detected G sensor output value is recorded on the CF card 11 without erasing the sensor output value.

  If the G sensor output value is small (for example, 0.4 G or more and less than 2 G) and the detection time is short (for example, several tens of milliseconds), it means that the vehicle 3 has passed through a step or a rough road. If the G sensor output value is small and the detection time is long (for example, 100 milliseconds or more), it means that the vehicle 3 has suddenly braked. When the G sensor output value is large (for example, 2G or more) and the detection time is short, it means that the vehicle 3 has caused an accident. The applicant of the present application stores trend data based on the relationship between the magnitude of the G sensor output value and its detection time in the memory of the center device or the like through experiments or the like.

  FIG. 24 is a flowchart showing a basic operation by G sensor and external switch detection. FIG. 25 is a diagram illustrating the relationship between the threshold of the G sensor output and the determination time. FIG. 26 is a timing chart showing the relationship between the Hi / Lo signal and its determination time. This flow starts under the condition that the ACC signal supplied from the accessory power supply is turned on or the control device 2 is turned on. Moreover, this flow is terminated under the condition that the ACC signal supplied from the accessory power supply is turned off or the control device 2 is turned off.

  In step a1 after the start, the first CPU 13 determines whether or not the periodic sensing timing t1 (t1 is, for example, 10 milliseconds) of the G sensor 27 has elapsed (see FIG. 25). If the determination is “NO”, the process proceeds to step a2. When it is determined that t1 has elapsed, the first CPU 13 records the G sensor output value in the second SD-RAM 30 and determines whether or not the G sensor output value is larger than the threshold value in step a4. Judging. If the determination is “NO”, the process returns to step a2.

  When the determination is “NO”, the process proceeds to step a5, and the first CPU 13 determines whether or not a predetermined threshold determination time Tg has elapsed. The threshold determination time Tg is set larger than the sensing timing t1. Timing of the threshold determination time Tg is started from the time when the G sensor output value exceeds the threshold, and when the continuous time exceeding the threshold reaches the time Tg, it is determined that the threshold determination time Tg has elapsed. If it is determined that the threshold determination time Tg has not elapsed, the process returns to step a2. If it is determined that the threshold determination time Tg has elapsed, the process proceeds to step a6. Here, the first CPU 13 detects that the vehicle 3 is driving dangerously. Next, proceeding to step a7, the first CPU 13 causes the CF card 11 to record the image information recorded in the second SD-RAM 30. Thereafter, the process returns to step a1. By providing such a threshold determination time Tg, malfunctions such as noise can be prevented.

  In step a2, the first CPU 13 determines whether or not the periodic sensing timing t2 (t2 is, for example, 100 milliseconds) of the external switch 49 has elapsed (see FIG. 26). When the determination is “NO”, the process returns to step a1. The process proceeds to step a8 when it is determined that t2 has elapsed, and the first CPU 13 determines whether or not the external switch 49 is turned on, and returns to step a1 when it is determined as “NO”. If it is determined that the signal is turned on, the process proceeds to step a9, and the first CPU 13 determines whether or not a predetermined signal determination time Tsw has been reached. This signal determination time Tsw is set larger than the sensing timing t2. Timing of the signal determination time Tsw is started from the time when the signal is switched from off to on, and when the continuous continuous time reaches the time Tsw, it is determined that the signal determination time Tsw has elapsed. If it is determined that the signal determination time Tsw has not elapsed, the process returns to step a1. If it is determined that the signal determination time Tsw has elapsed, the process proceeds to step a10, the first CPU 13 detects the external switch 49, and then proceeds to step a7. By providing the signal determination time Tsw, malfunctions such as noise can be prevented.

  FIG. 27 is a flowchart showing a process of outputting synthesized speech by the AVM-ECU. This flow starts under the condition that the ACC signal supplied from the accessory power supply is turned on or the control device 2 is turned on. Moreover, this flow is terminated under the condition that the ACC signal supplied from the accessory power supply is turned off or the control device 2 is turned off. When the first CPU 13 detects a dangerous driving of the vehicle 3 in step d1 after the start, the process proceeds to step d2 and the first CPU 13 makes a warning sound output request to the second CPU 31 of the control device 2.

  On the control device 2 side, when the second CPU 31 receives the warning voice output request at step E1, at step Eout, the second CPU 31 synthesizes voice to the speaker SP (see FIG. 7). Please output "speech synthesis". While the vehicle 3 is receiving instructions from the center 4 (step E2: YES), the second CPU 31 ends this process without causing the speaker SP to output sound. If no instruction is being received, the speech synthesis is output to the speaker SP.

  FIG. 28 is a flowchart showing processing for correcting the offset of the G sensor 27 by the memory switch 60. This flow starts under the condition that the ACC signal supplied from the accessory power supply is turned on or the control device 2 is turned on. Moreover, this flow is terminated under the condition that the ACC signal supplied from the accessory power supply is turned off or the control device 2 is turned off. This flow is an operation by the first CPU 13.

  After the start, in step f1, it is determined whether or not command information is given from the memory switch 60. If given, the process proceeds to step f2, and if not, the process proceeds to step f3. In step f2, since the command information is given, each part is controlled so that the operation information stored in the first RAM 12 is written in the CF card 11, and the process returns to step f1.

  In step f3, it is determined whether or not the specific information is given from the memory switch 60. If given, the process proceeds to step f4. If not given, the process returns to step f1. In step f4, since the specific information is given, as described above, the offset in the front-rear direction, the left-right direction, and the up-down direction of the G sensor 27 is corrected, and the process returns to step f1.

  According to the drive recorder 1 according to the present embodiment described above, a plurality of driving information (image, G value, position, time, vehicle speed, voice, etc.) is recorded endlessly in the second SD-RAM 30. As described above, the image, G value, position, time, vehicle speed, and sound are recorded on the card based on the trigger such as the G sensor.

  If the first CPU 13 determines that the command information is specific information, the first CPU 13 corrects the offset of the G sensor 27. In other words, the initial value of the G sensor 27 is set. Therefore, the memory switch 60 is originally a means for inputting command information for instructing a writing operation. However, if the command information input by the memory switch 60 is specific information, the initial value of the G sensor 27 as described above. Is set. Thus, the initial value of the G sensor 27 can be set using the memory switch 60. Therefore, in order to simplify the configuration of the first drive 1, the LCD controller 28 is connected to the LCD controller connector 22 without providing a dedicated means for setting the initial value of the G sensor 27. The offset correction can be easily set using the memory switch 60 without shifting to the maintenance mode for setting and inspecting the main body 5. This improves convenience.

  Next, the drive recorder 1 according to the second embodiment of the present invention will be described. FIG. 29 is a perspective view of the drive recorder 1 according to the present embodiment, and FIG. 30 is a front view of the drive recorder 1. The first Draco 1 according to the present embodiment is characterized in that it further includes a power switch 61 as a power supply means. In the first drive recorder 1 according to the first embodiment described above, the first power supply unit 26 is configured to start up based on the power supply activation signal supplied from the control device 2. In the drive 1, the power-on information is given to the first CPU 13 by operating the power switch 61. The first CPU 13 is configured to start up the first power supply unit 26 based on power-on information that is startup information from the power switch 61.

  The power switch 61 is electrically connected to the first CPU 13. The power switch 61 can input power-on information for activating the first drive 1.

  The first CPU 13 has a function as a determination unit, and determines whether command information input by the memory switch 60 and power-on information input by the power switch 61 are input simultaneously. The command information is information given by operating the memory switch 60 as described above, as described above, and is information based on a predetermined number of times, for example, one operation within a predetermined time, for example, 1 second. It is. The power-on information is information given by operating the power switch 61 as described above, as described above, and is based on a predetermined number of times, for example, once during a predetermined time, for example, 1 second. Information.

  Further, the first CPU 13 has a function as a setting means, and when it is determined that the command information given from the memory switch 60 and the power-on information given from the power switch 61 are inputted simultaneously, the same as in the first embodiment described above. The value detected by the G sensor 27 is set to a predetermined initial value. Here, “simultaneously” is not limited to the case where each information is given completely at the same time, and it is sufficient that at least one period of the period in which the command information is given to the first CPU 13 and the period in which the power-on information is given overlap. .

  FIG. 31 is a flowchart showing processing for correcting the offset of the G sensor 27 by the memory switch 60 and the power switch 61. This flow starts under the condition that the ACC signal supplied from the accessory power supply is turned on. Also, this flow ends under the condition that the ACC signal supplied from the accessory power supply is turned off. This flow is an operation by the first CPU 13.

  In step g1 after the start, it is determined whether or not command information is given from the memory switch 60. If given, the process proceeds to step g2, and if not, the process proceeds to step g4. In step g2, it is determined whether or not the power-on information is given from the power switch 61 during the period when the command information is given. If given, the process proceeds to step g3. If not given, step g6 is given. Migrate to

  In step g6, since only the command information is given, each unit is controlled so that the operation information stored in the first RAM 12 is written in the CF card 11, and the process returns to step g1. In step g3, since the command information and the power-on information are simultaneously given, the front / rear direction, left / right direction, and vertical direction offset of the G sensor 27 are corrected as described above, and the process returns to step g1.

  In step g4, it is determined whether or not the power-on information is given from the power switch 61. If given, the process proceeds to step g5, and if not given, the process returns to step g1. In step g5, since only the power-on information is given, the first power supply unit 26 is started and the process returns to step g1.

  According to the drive recorder 1 according to the present embodiment described above, when the first CPU 13 determines that the command information given from the memory switch 60 and the power-on information given from the power switch 61 are input simultaneously, the G sensor 27 The value to be detected is set to a predetermined initial value. The memory switch 60 is originally a means for inputting command information for instructing the writing operation, and the power switch 61 is originally a means for inputting power-on information for starting the drive recorder 1, but each switch 60, When the information input by 61 is input simultaneously, the initial value of the G sensor 27 is set as described above. Since these switches 60 and 61 are not input simultaneously in a normal operation, the initial value of the G sensor 27 can be set by such a special operation. Therefore, in order to simplify the configuration of the first drive 1, the LCD controller 28 is connected to the LCD controller connector 22 without providing a dedicated means for setting the initial value of the G sensor 27. The offset correction can be easily set using the memory switch 60 and the power switch 61 without shifting to the maintenance mode for setting and inspecting the main body 5. This improves convenience.

  Next, a drive recorder 1 according to the third embodiment of the present invention will be described. The first Draco 1 according to the present embodiment is realized by the remaining configuration excluding the configuration related to GPS from the first Draco 1 shown in FIG. 2 of the first embodiment described above. The position information and the time information can be acquired by the configuration related to GPS. However, if these configurations are not available, the driver needs to set the time information. In the present embodiment, the memory switch 60 can input command information for instructing an operation to write operation information stored in the first RAM 12 to the CF card 11, and can be input by the first CPU 13 by performing a predetermined operation. The clocked time can be corrected.

  The first CPU 13 has a function as a time measuring means and keeps time. Therefore, the image capturing time and the like are determined based on the time information timed by the first CPU 13.

  The first CPU 13 also has a function as a determination unit, and determines whether or not the command information input by the memory switch 60 is predetermined specific information. The command information is information given by operating the memory switch 60 by a normal switch, and is information based on a predetermined number of times, for example, one operation within a predetermined time, for example, 1 second. The specific information is information given by operating the memory switch 60 as a special switch that is not normal, and is information based on a predetermined number of times, for example, twice during a predetermined time, for example, 1 second. is there. Further, for example, the specific information is information based on the operation of the memory switch 60 continuously for a predetermined time, for example, 5 seconds. Therefore, the first CPU 13 can determine whether the command information given from the memory switch 60 is specific information.

  Further, the first CPU 13 has a function as setting means, and when the command information given from the memory switch 60 is determined to be the specific information, the first CPU 13 sets the time counted by the first CPU 13 to a predetermined time. Therefore, the time is corrected by specially operating the memory switch 60 as described above. For example, if the above-mentioned specific information is given to the first CPU 13 during a period from (T-1) 30 minutes to T hours 29 minutes (T is an integer from 1 to 24), the current time is set to T hours. It is configured to set to 00 minutes 00 seconds. In this case, for example, when the current time is 11:38, the current time is set to 12:00:00 by inputting specific information through the memory switch 60.

  Also, for example, if the above-mentioned specific information is given to the first CPU 13 during a period from (T-1) time 45 minutes to T time 14 minutes, the current time is set to T hours 00 minutes 00 seconds and the current time is When the above-mentioned specific information is given to the first CPU 13 during a period from T: 15 to T: 44, the current time may be set to T: 30: 00. In this case, for example, when the current time is 11:38, the specific time is input by the memory switch 60, so that the current time is set to 11:30:30. For example, when the current time is 12:02, the current time is set to 12:00:00 by inputting specific information through the memory switch 60.

  FIG. 32 is a flowchart showing a process for correcting the time by the memory switch 60. This flow starts under the condition that the ACC signal supplied from the accessory power supply is turned on. Also, this flow ends under the condition that the ACC signal supplied from the accessory power supply is turned off. This flow is an operation by the first CPU 13.

  In step h1 after the start, it is determined whether or not command information is given from the memory switch 60. If given, the process proceeds to step h2, and if not, the process proceeds to step h3. In step h2, since command information is given, each part is controlled so that the operation information stored in the first RAM 12 is written in the CF card 11, and the process returns to step h1.

  In step h3, it is determined whether or not specific information is given from the memory switch 60. If given, the process proceeds to step h4. If not given, the process returns to step h1. In step h4, since the specific information is given, the time is corrected as described above, and the process returns to step h1.

  According to the drive recorder 1 which concerns on this embodiment demonstrated above, 1st CPU13 will correct | amend time, if command information is judged to be specific information. The memory switch 60 is originally a means for inputting command information for instructing a writing operation. If the command information input by the memory switch 60 is specific information, the current time is set to a predetermined time as described above. Is set. As a result, the current time can be set using the memory switch 60. Therefore, in order to simplify the configuration of the first drive recorder 1, even if there is no configuration related to GPS and there is no function to automatically correct the current time, a dedicated switch means for setting the time is provided. The time can be easily set by using the memory switch 60 without connecting the LCD controller 28 to the LCD controller connector 22 and shifting to the maintenance mode for setting and inspecting the drive recorder body 5. be able to. This improves convenience.

  Next, a drive recorder 1 according to a fourth embodiment of the present invention will be described. The present embodiment is similar to the drive recorder 1 according to the second embodiment described above, and is characterized in that a power switch 61 is further provided.

  The first CPU 13 has a function as a determination unit, and determines whether command information input by the memory switch 60 and power-on information input by the power switch 61 are input simultaneously. The command information is information given by operating the memory switch 60 as described above, as described above, and is information based on a predetermined number of times, for example, one operation within a predetermined time, for example, 1 second. It is. The power-on information is information given by operating the power switch 61 as described above, as described above, and is based on a predetermined number of times, for example, once during a predetermined time, for example, 1 second. Information.

  Further, the first CPU 13 has a function as setting means, and when it is determined that the command information given from the memory switch 60 and the power-on information given from the power switch 61 are inputted simultaneously, the same as in the third embodiment. In addition, the time measured by the first CPU 13 is set to a predetermined time.

  FIG. 33 is a flowchart showing a process for correcting the time by the memory switch 60 and the power switch 61. This flow starts under the condition that the ACC signal supplied from the accessory power supply is turned on. Also, this flow ends under the condition that the ACC signal supplied from the accessory power supply is turned off. This flow is an operation by the first CPU 13.

  In step i1 after the start, it is determined whether or not command information is given from the memory switch 60. If given, the process proceeds to step i2, and if not, the process proceeds to step i4. In step i2, it is determined whether or not the power-on information is given from the power switch 61 during the period when the command information is given. If given, the process proceeds to step i3. If not given, step i6 is given. Migrate to

  In step i6, since only the command information is given, each part is controlled so that the operation information stored in the first RAM 12 is written in the CF card 11, and the process returns to step i1. In step i3, since the command information and the power-on information are simultaneously given, the time is corrected as described above, and the process returns to step i1.

  In step i4, it is determined whether or not power-on information is given from the power switch 61. If it is given, the process proceeds to step i5, and if not, the process returns to step i1. In step i5, since only the power-on information is given, the first power supply unit 26 is activated and the process returns to step i1.

  According to the drive recorder 1 according to the present embodiment described above, when the first CPU 13 determines that the command information given from the memory switch 60 and the power-on information given from the power switch 61 are simultaneously input, the first CPU 13 counts time. The time to be set is set to a predetermined time. The memory switch 60 is originally a means for inputting command information for instructing the writing operation, and the power switch 61 is originally a means for inputting power-on information for starting the drive recorder 1, but each switch 60, When the information input by 61 is input simultaneously, the time to be timed is set to a predetermined time as described above. Since these switches 60 and 61 are not input simultaneously in a normal operation, the time can be set to a predetermined time by such a special operation. Therefore, in order to simplify the configuration of the first drive recorder 1, even if there is no configuration related to GPS and there is no function to automatically correct the current time, a dedicated switch means for setting the time is provided. Without using the memory switch 60 and the power switch 61, the LCD controller 28 is connected to the LCD operator connector 22 and the maintenance mode for setting and inspecting the drive recorder 5 is not used. It can be set easily. This improves convenience.

  Next, a drive recorder 1 according to a fifth embodiment of the present invention will be described. The first draco 1 according to the present embodiment is similar to the first draco 1 of the third embodiment described above, and is realized by the remaining configuration excluding the configuration related to GPS.

  As described above, the drive recorder 1 is configured so that data can be recorded even when the ACC signal is off and the second power supply unit 43 of the control device 2 is off (falling signal in FIG. 12). The end control is performed by. During this end control, the first CPU 13 performs control so that the time when the ACC signal is turned off (sometimes referred to as off time) is recorded in the CF card 11.

  The center device is configured to be able to analyze and output information recorded on the CF card 11. When the center device reads the information recorded on the CF card 11 by the reading means in order to analyze the information recorded on the CF card 11, the latest off time stored in the CF card 11 and the center device Compare with the current time. As a result of this comparison, when a predetermined time, for example, 24 hours has elapsed since the off time, the center device notifies that the predetermined time has elapsed by a notification means such as the display 4a. The display 4a displays, for example, a sentence “Please check whether the time setting of the in-vehicle device set in the vehicle number * is correct”. However, the “*” is an integer.

  Next, the operation of the drive recorder 1 of the present embodiment will be described using a flowchart. FIG. 34 is a flowchart showing a process for recording the off time. This flow starts under the condition that the ACC signal supplied from the accessory power supply is turned on. Also, this flow ends under the condition that the ACC signal supplied from the accessory power supply is turned off. This flow is an operation by the first CPU 13.

  In step j1, it is determined whether or not the ACC signal is turned off. If turned off, the process proceeds to step j2, and if not turned off, step j1 is repeated. In step j2. Since the ACC signal is turned off, control is performed so that the off time when the ACC signal is turned off is written to the CF card 11, and the process returns to step j1.

  By processing in this way, the time when the ACC signal is turned off is written in the CF card 11.

  FIG. 35 is a flowchart showing processing for prompting time correction. This flow is performed by the control device of the center device, and is started when the center device is powered on. In addition, this flow ends under the condition that the center device is powered off. In step k1, it is determined whether or not the CF card 11 is inserted. If it is inserted, the process proceeds to step k2, and if not, step k1 is repeated.

  In step k2, the latest off time recorded on the CF card 11 is read, and the process proceeds to step k3. In step k3, the current time measured by the center device is compared with the latest off time. If a predetermined time, for example, 24 hours has elapsed from the off time, the process proceeds to step k4, and the time has not elapsed. Return to step k1. In step k4, it is notified that a predetermined time has elapsed from the off time, and the process returns to step k1.

  By processing in this way, the operator of the center device can recognize that a predetermined time has elapsed since the latest OFF time recorded on the CF card 11.

  According to the drive recorder 1 according to the present embodiment described above, the first CPU 13 records the off time when the ACC signal is turned off on the CF card 11. Therefore, in order to simplify the configuration of the first Draco 1, even if there is no means for notifying the time that the first Draco 1 is timing, the driver can set the time that the 1st Draco 1 is timing. This can be confirmed based on the off time recorded on the CF card 11.

  In addition, the center device notifies that the time measured by the center device has elapsed from the latest OFF time recorded in the CF card 11 when a predetermined time has elapsed. Since the period from the off time when the ACC signal is turned off to the read time for reading the CF card 11 into the center device is almost constant, in such a case, the off time and the current time are compared as described above. Thus, it can be recognized that the time measured by the drive recorder 1 is deviated from the current time. Therefore, in order to simplify the configuration of the first Draco 1, even if there is no configuration related to GPS and there is no function to automatically correct the current time, so that the time lag is automatically recognized. Therefore, it is possible to prompt the driver to correct the time based on such a time lag. This improves convenience.

  Further, when the time to stop the vehicle is constant to some extent, the off time when the ACC signal is turned off is constant to some extent, and the time for the CF card 11 to be read by the center device is often constant. Even if it is a case, it has an effect | action and effect similar to the above-mentioned.

  In the first to fourth embodiments described above, either the offset correction of the G sensor 27 or the time correction is realized by the memory switch 60, but the present invention is not limited to either one. You may comprise so that one correction | amendment can be performed. For example, the two corrections can be corrected by one memory switch 60 by setting the specific information for offset correction and the specific information for time correction to be different from each other.

  Further, for example, a plurality of pieces of specific information may be set, and the degree of offset correction and the degree of time correction may be individually set corresponding to the plurality of pieces of specific information. As a result, operability can be improved.

  Moreover, when specific information is input by the memory switch 60 and the power switch 61, it is preferable to set the light emission mode of the LED 18 to be changed individually so that the driver can recognize that the specific information has been input. Thus, the driver can recognize whether or not the specific information can be input by the light emission form of the LED 18 and can prevent an erroneous operation.

It is a perspective view showing the relationship between the drive recorder 1 and the control apparatus 2 which concern on the 1st Embodiment of this invention. It is the perspective view of the modified form which changed the drive recorder 1 partially. FIG. 4 is a diagram for explaining a camera mounting position on a vehicle 3. 4A is a diagram showing the center 4, FIG. 4A is a diagram showing the center device configuration, and FIG. 4B is a diagram in which a traveling locus, a captured image, and a G sensor measurement value of the vehicle 3 are output to the display 4a. It is a figure showing an aspect. 1 is a perspective view of a drive recorder 1. FIG. 1 is a front view of a drive recorder 1. FIG. 2 is a block diagram showing an electrical configuration of a drive recorder 1, a control device 2, and a center 4. FIG. 2 is a block diagram showing an electrical configuration of the drive recorder 1. FIG. 3 is a block diagram illustrating an electrical configuration of a control device 2. FIG. 3 is a block diagram illustrating an electrical configuration of a main part of the control device 2. FIG. 2 is a block diagram illustrating an electrical configuration of a main part of the drive recorder 1. FIG. It is a figure explaining the delay circuit which resets by hardware, when a watchdog pulse stops or does not operate | work with a regular period. It is a block diagram showing the electric constitution of the principal part concerning the modification which changed drive recorder 1 partially. It is a figure showing the relationship between a part of image information, position information, etc. It is a figure showing the aspect by which still image information is recorded on the CF card 11 at fixed intervals (delta) based on G sensor output value. 6 is a diagram illustrating a relationship between a G sensor output value 48 that exceeds a threshold and a recording range Rh of image information recorded on the CF card 11. FIG. It is a figure for demonstrating the threshold value determination method of G sensor output value. 6 is a diagram illustrating a relationship between an ON signal S3 of the photographing switch 9 and a recording range Rh of image information recorded on the CF card 11. FIG. 6 is a diagram illustrating a relationship between reception of a shooting request command by communication and a recording range Rh of image information recorded on the CF card 11. FIG. It is a block diagram explaining the various acquisition of a trigger in the drive recorder.

It is a figure showing the aspect which emits warning information based on the threshold value of operation data. It is a figure showing the relationship between G sensor output value and detection time. It is a chart showing the tendency based on the relationship between the magnitude of G sensor output value and its detection time. It is a flowchart showing the basic operation | movement by G sensor and external switch detection. It is a figure showing the relationship between the threshold value of G sensor output, and its determination time. It is a timing chart showing the relationship between a Hi / Lo signal and its determination time. It is a flowchart showing the process which outputs a synthetic | combination voice with a control apparatus. 5 is a flowchart showing a process for correcting the offset of the G sensor 27 by a memory switch 60. It is a perspective view of the drive recorder 1 which concerns on the 2nd Embodiment of this invention. 1 is a front view of a drive recorder 1. FIG. 10 is a flowchart showing a process for correcting the offset of the G sensor 27 by the memory switch 60 and the power switch 61. 4 is a flowchart showing a process for correcting time by a memory switch 60. 4 is a flowchart showing a process for correcting time by a memory switch 60 and a power switch 61. It is a flowchart showing the process which records off time. It is a flowchart showing the process which accelerate | urge | promotes time correction.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Drive recorder 2 Control apparatus 3 Vehicle 5 Drive recorder main body 6 Camera 7 Microphone 11 CF card 12 1st RAM
13 First CPU
60 Memory switch 61 Power switch

Claims (2)

In a driving information recording device for circulating driving information related to vehicle driving in a storage means and storing the driving information stored in the storage means on a recording medium,
Acceleration detecting means for detecting the acceleration of the vehicle;
By the first operation, command information for instructing an operation for writing the operation information stored in the storage means to the recording medium, and specific information based on a predetermined second operation different from the first operation are input. Input means;
Determining means for determining whether the information input by the input means is the specific information;
When the determination means determines that the information input by the input means is the specific information, the value detected by the acceleration detection means is set as an initial value for correcting the offset of the acceleration detection means. Setting means;
A driving information recording apparatus comprising: It further comprises power supply means for inputting activation information for activating the operation information recording device,
The determination means determines whether the activation information and the command information are input simultaneously,
When the determination unit determines that the activation information and the command information are input simultaneously, the setting unit sets a value detected by the acceleration detection unit as an initial value for correcting the offset of the acceleration detection unit. The driving information recording apparatus according to claim 1, wherein the driving information recording apparatus is set.

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