JP5555576B2 - Lighting device - Google Patents

Description

  The present invention relates to an illuminating device, and relates to an illuminating device including a plurality of light sources that illuminate a display unit, and a disconnection detecting unit that detects disconnection of the plurality of light sources.

  A moving body such as an automobile is equipped with a display device that displays the state of the moving body measured by various measuring means to passengers of the moving body. As such a display device, for example, a meter unit 1 shown in FIGS. 1 to 3 attached to an instrument panel of a vehicle has been proposed (Patent Document 1).

  As shown in the figure, the meter unit 1 includes a display unit indispensable for vehicle operation such as a speedometer 4b and an odd trip display unit 5b, and a display unit having an optional tendency such as a tachometer 4a and a clock display unit 5a. And are provided. These display units are illuminated with a light source such as an LED disposed on the back surface at night. Such illumination is supported by high quality and hardly breaks down. However, in rare cases, disconnection may occur. In this case, the display balance may be lost and the appearance may deteriorate.

  For example, as shown in FIG. 3, the tachometer 4a has a plurality of tachometer light sources L21 to L28 arranged in an arc shape around the rotation axis of the pointer 42a on the back surface of the dial 41a. The plurality of tachometer light sources L21 to L28 are arranged so as to be symmetrical with respect to an axis of symmetry A2 passing through the rotation axis of the pointer 42a and extending along the vertical direction Y2. For example, if only the tachometer light source L21 is disconnected and disappears among the plurality of tachometer light sources L21 to L28, the left and right illumination balance centered on the symmetry axis A2 is lost and the appearance is deteriorated.

  Further, for example, as shown in FIG. 1, the odd-trip display unit 5b and the clock display unit 5a are configured by a liquid crystal display or the like, and pass through the center of the meter unit 1 and have an axis of symmetry A1 along the vertical direction Y2. With respect to each other. For this reason, for example, when only the light source of the odo trip display section 5b out of the odo trip display section 5b and the clock display section 5a is turned off, the left and right display balance around the symmetry axis A1 is lost, and the appearance is deteriorated.

JP 2008-286575 A

  Therefore, an object of the present invention is to provide an illumination device that prevents display balance from being lost and does not deteriorate in appearance even when a disconnection occurs.

The invention according to claim 1 for solving the above-described problem is an illuminating apparatus including a plurality of light sources that illuminate a display unit, and a disconnection detection unit that detects disconnection of the plurality of light sources . A light source is arranged so as to be line-symmetric with respect to one of the display units, and when disconnection is detected by the disconnection detecting means , the light source is symmetrical with respect to the light source in which the disconnection is detected among the plurality of light sources . The illumination device further includes an extinguishing unit that extinguishes the light source arranged at the position .

The invention according to claim 2 is for a plurality of speedometers, wherein the display unit is provided with a plurality of speedometers and a first display unit other than the speedometer, and the plurality of light sources illuminate the speedometer. A light source and a plurality of first display light sources that illuminate the first display unit, and the extinguishing means is the first display unit of the speedometer light source and the first display light source. Only when the optical light source is disconnected, the first display light source arranged at a line symmetry position with respect to the first display light source in which the disconnection is detected is turned off, and the speedometer light source is not turned off. It lies in the illumination apparatus according to claim 1, wherein the.

According to a third aspect of the present invention, the display unit is provided with a plurality of odd-trip display units arranged in line symmetry with each other and a second display unit other than the odd-trip display unit, and the plurality of light sources Is composed of a light source for an odo trip display section that illuminates the odo trip display section, and a light source for a second display section that illuminates the second display section, and the light-off means includes the odo trip display. Only when the odd-trip display light source is disconnected among the light source for display and the second display light source, the second display light source is turned off, and the second display light source is disconnected 3. The illumination device according to claim 1, wherein the light source for the odd trip display unit is not turned off.

As described above , according to the first aspect of the present invention, the extinguishing means extinguishes the light source arranged at the line-symmetrical position with respect to the light source where the disconnection is detected. The display balance is not lost, so the appearance does not deteriorate.

According to the invention described in claim 2 , the light-off means is a light source corresponding to the light source in which the disconnection is detected only when the first display light source is disconnected from the speedometer light source and the first display light source. Since the speedometer light source that illuminates the speedometer is not turned off, it is possible to prevent the speedometer indispensable for driving the vehicle from becoming difficult to see.

According to the invention described in claim 3 , since the extinguishing means turns off only the light source for the second display unit among the light source for the odo trip display unit and the light source for the second display unit, the symmetry axis is maintained even if the disconnection occurs. Since the central display balance is not lost, the appearance does not deteriorate. Even if the light source for the second display section is disconnected, the light source for the odo trip display section that illuminates the odo trip display section is not turned off. be able to.

It is a front view which shows one Embodiment of the meter unit incorporating the illuminating device of this invention. It is the II sectional view taken on the line of FIG. It is explanatory drawing for demonstrating the arrangement position of the light source for tachometers which comprises the tachometer shown in FIG. It is a circuit diagram which shows the electric constitution of the meter unit shown in FIG. It is a table | surface which shows the table which defined the light source by which the disconnection was detected in the light source for tachometers, and the light source made to light-off correspondingly. It is a table | surface which shows the table which defined the relationship of the disconnection and light extinction of the light source for odd trip display parts, and the light source for timepiece display parts. It is a flowchart which shows the process sequence of CPU shown in FIG. It is a flowchart which shows the detail of the disconnection detection process shown in FIG.

  Hereinafter, the illumination device of the present invention will be described with reference to the drawings. FIG. 1 is a front view showing an embodiment of a meter unit incorporating the illumination device of the present invention. 2 is a cross-sectional view taken along the line II of FIG. The meter unit 1 is attached to an instrument panel of a vehicle, and displays the status of the moving body measured by various measuring means to the passenger of the moving body.

  As shown in FIG. 1, the meter unit 1 includes, as shown in FIG. 1, a shift indicator 2 that indicates the position of the shift lever of the vehicle, a turn R3a and a turn L3b that indicate the position of the vehicle's turn lever, and the engine speed. Tachometer 4a (= display unit, first display unit) for displaying, speedometer 4b (= display unit) for displaying vehicle speed, and clock display unit 5a (= display unit, second display unit) for displaying time ), An odo trip display section 5b (= display section) for displaying odo trip, a fuel gauge 6a for displaying the remaining amount of fuel, and a water temperature gauge 6b for displaying the temperature of the engine cooling water. .

  As shown in FIG. 2 and the like, the meter unit 1 further includes a printed circuit board 7 on which various electronic components are mounted, a case 8 that accommodates the printed circuit board 7 and the like, a back cover 9 that covers the back surface of the case 8, A front glass 10 that covers the front of the case 8 and a turn-back 11 that hides a display unnecessary portion of the meter unit 1 are provided.

  As shown in FIG. 1, the shift indicator 2 includes a “P” indicator 21 that indicates a parking state, an “R” indicator 22 that indicates reverse travel, an “N” indicator 23 that indicates a neutral state, and a “ D ”indicator 24,“ 2 ”indicator 25 indicating a state controlled in the first and second speed ranges, and“ L ”indicator 26 indicating a fixed first speed state, which are on axis A1. Are arranged side by side. The axis A1 is an axis that passes through the center of the meter unit 1 in the left-right direction Y1 and is parallel to the vertical direction Y2. Further, these “P”, “R”, “N”, “D”, “2”, and “L” indicators 22 to 26 are illuminated and radiated by the light source L (FIG. 4) arranged on the back surface thereof. .

  The turn R3a indicates that the turn lever is at the right turn instruction position. The turn L3b indicates that the turn lever is at the left turn instruction position. The turn R3a and the turn L3b are arranged in line-symmetric positions with respect to the axis A1 as a symmetry axis. Further, the turn R3a and the turn L3b are illuminated by the light source L (FIG. 4) disposed on the back surface thereof and shine.

  The tachometer 4a and the speedometer 4b are constituted by a pointer device, and are arranged at line symmetrical positions with the axis A1 as a symmetry axis. As shown in FIG. 1 and FIG. 2, the tachometer 4a includes a dial 41a having a display design such as scales, numbers, letters or symbols indicating the engine speed on the surface, and the front face of the dial 41a. The pointer 42a disposed on the dial 41, the movement 43a (FIGS. 2 and 4) which is disposed on the back of the dial 41a and rotates the pointer 42a according to the measured amount of the engine speed, and the dial 41a is illuminated from the back. A plurality of tachometer light sources L21 to L28 (FIGS. 3 and 4) and a reflecting surface 44a (FIG. 2) for reflecting light from the tachometer light sources L21 to L28 to the dial 41a.

  As with the tachometer 4a, the speedometer 4b includes a dial 41b having a display design such as scales, numbers, characters or symbols indicating speed on the surface, as shown in FIG. 1 and the like, and the dial 41b. A pointer 42b disposed in front of the dial 42, a movement 43b (FIG. 4) that is mounted on the back of the dial 41b and rotates the pointer 42b in accordance with a measured amount of vehicle speed, and a plurality of lights that illuminate the dial 41b from the back Speedometer light sources L31 to L38 (FIG. 4) and a reflecting surface (not shown) that reflects light from the speedometer light sources L31 to L38 to the dial 41b.

  The dial plates 41a and 41b are composed of a disk-shaped transparent substrate, a colored transmission layer that is provided in front of the transparent substrate and represents the display design, and a light shielding layer from which the display design is removed. The movement 43a of the tachometer 4a and the movement 43b of the speedometer 4b are mounted on the printed circuit board 7 disposed on the back of the dial plates 41a and 41b.

  Further, the tachometer light sources L21 to L28 and the speedometer light sources L31 to L38 are also arranged on the printed circuit board 7. Further, as shown in FIG. 3, the tachometer light sources L <b> 21 to L <b> 28 are arranged at mutually symmetrical positions with the axis A <b> 2 as the symmetry axis. The axis A2 is an axis that passes through the center of the dial 41a, that is, the rotation axis of the pointer 42a and is parallel to the vertical direction Y2. In FIG. 3, X1 to X8 are illumination areas of the light sources L21 to L28 for the tachometer. Similarly, the speedometer light sources L31 to L38 are arranged at line-symmetrical positions with the center of the dial 41b, that is, an axis (not shown) passing through the rotation axis of the pointer 42b and parallel to the vertical direction Y2 as the symmetry axis.

  The fuel gauge 6a and the water temperature gauge 6b are constituted by a pointer device, and are arranged in line-symmetric positions with the axis A1 as a symmetry axis. As shown in FIG. 1, the fuel gauge 6a and the water temperature gauge 6b have a display design such as scales, numbers, letters or symbols indicating the remaining amount of fuel and water temperature on the surface, as shown in FIG. A dial 61 formed with a dial, a pointer 62 disposed in front of the dial 61, and a movement (not shown) that is mounted on the back of the dial 61 and rotates the pointer 62 in accordance with a measured amount of vehicle speed. And a plurality of light sources L (FIG. 4) for illuminating the dial 61 from the back.

  As shown in FIG. 4 and the like, the clock display unit 5a includes a liquid crystal display unit (hereinafter referred to as LCD) 51a and clock display unit light sources L41 to L4n that illuminate the LCD 51a from the back. The LCD 51a is disposed in an opening provided below the dial 41a, and the clock display light sources L41 to L4n are disposed on the printed circuit board 7.

  As shown in FIG. 4 and the like, the odd trip display unit 5b includes an LCD 51b and odd-trip display light sources L51 to L5n that illuminate from the back of the LCD 51b. The LCD 51b is disposed in an opening provided below the dial 41b, and the odd / trip display light sources L51 to L5n are disposed on the printed circuit board 7. The timepiece display unit 5a and the trip display unit 5b are arranged in line-symmetric positions with the axis A1 as the axis of symmetry.

  Next, an electrical configuration diagram of the meter unit 1 having the above-described configuration will be described with reference to FIG. The meter unit 1 performs various processes and controls according to a predetermined program, controls the entire unit, a ROM 13 that is a read-only memory storing a program for the CPU 12, and various data. And a RAM 14 that is a readable / writable memory having an area necessary for processing operations of the CPU 12 while storing.

  The CPU 12 operates by receiving power supply from the power supply circuit 15. The power supply circuit 15 generates the drive voltage Vcc of the CPU 12 from the power supply from the battery + B and supplies it to the CPU 12. The reset terminal of the CPU 12 is connected to the ignition switch IGN + via the I / F 16a, and is reset when the ignition switch IGN + is turned off. The CPU 12 is connected to the CAN via the I / F 16b, and receives measurement values such as the engine speed and the vehicle speed measured by various measuring means from the CAN. The CPU 12 is connected to a nonvolatile EEPROM 17 and an odd trip switch SW.

  The CPU 12 is connected to a motor driver 18 for supplying a driving voltage to a movement 43a of the tachometer 4a, a movement 43b of the speedometer 4b, a fuel gauge 6a, and a movement (not shown) of the water temperature gauge 6b, and received from the CAN. By controlling the motor driver 18 based on the measured values, the movement 43a of the tachometer 4a, the movement 43b of the speedometer 4b, the movement of the fuel gauge 6a, and the water temperature gauge 6b (not shown) are controlled.

  The CPU 12 is connected to the LCD drivers 19a and 19b, respectively, and controls the display of the LCD 51a and LCD 51b by controlling the LCD drivers 19a and 19b.

  The light source L, the light source L21 to L28 for the tachometer, the light sources L31 to L38 for the speedometer, the light sources L41 to L4n for the clock display unit, and the light sources L51 to L5n for the odd trip display unit are each composed of a light emitting diode. Both ends thereof are connected to the CPU 12, and the anode is connected to the drive voltage VH. The CPU 12 controls the lighting of the light emitting diodes by controlling the voltage between the anode and the cathode of these light emitting diodes. Specifically, the CPU 12 supplies the ground potential to both the anode and the cathode to turn off the light emitting diode, opens the anode, supplies the ground potential to the cathode, and applies the drive voltage VH between the anode and the cathode. Turn on the light emitting diode.

  Both ends of the light source L21 to L28 for the tachometer and the light sources L51 to L5n for the odd-trip display unit are connected to the CPU 12 via voltage dividing resistors R1 and R2, respectively. Further, the A / D converter 20 in which the connection point voltage Vc between the light source L21 to L28 for the tachometer and the light sources L51 to L5n for the odd-trip display unit and the voltage dividing resistor R1 is built in the CPU 12 via the resistor R3. It is connected to the.

  The A / D converter 20 converts the connection point voltage Vc to digital and supplies it to the CPU 12. The connection point voltage Vc is equal to the drive voltage VH when the tachometer light sources L21 to L28 and the odd-trip display light sources L51 to L5n are disconnected, and the tachometer light sources L21 to L28 and odd When the trip display light sources L51 to L5n are not disconnected, the drive voltage VH is divided by the voltage dividing resistors R1, R2, etc., and becomes a voltage smaller than the drive voltage VH. That is, the CPU 12 can detect the disconnection of each of the light sources L21 to L28 for the tachometer and the light sources L51 to L5n for the odd-trip display unit by the connection point voltage Vc.

  As shown in FIG. 5, the EEPROM 17 stores a table that defines light sources in which disconnections are detected in the light sources L21 to L28 for the tachometer and light sources to be turned off correspondingly. Specifically, as shown in FIG. 5, the table turns off the tachometer light source L28 when the tachometer light source L21 is disconnected, and turns off the tachometer light source L27 when the tachometer light sources L22 and L23 are disconnected. It is predetermined that L28 is extinguished.

  The table is determined in advance so that when the light sources L24 and L25 for the tachometer are disconnected, the other light sources are not turned off. Further, the table is determined in advance so that the tachometer light sources L23 to L21 are turned off when the tachometer light sources L26 to L28 are disconnected. That is, as is apparent from a comparison between FIGS. 3 and 5, this table is determined in advance so as to turn off the light sources arranged in line-symmetric positions with respect to the light source in which the disconnection is detected.

  In addition, as shown in FIG. 6, the EEPROM 17 records a table that defines that when the odd / trip display light sources L51 to L5n are disconnected, the clock display light sources L41 to L4n are turned off. Has been. As is apparent from a comparison between FIGS. 1 and 6, this table is arranged in a line-symmetrical position with respect to the odd-trip display portion 5b illuminated by the light sources L51 to L5n for the odd-trip display portion where disconnection is detected. The clock display unit light sources L41 to L4n that illuminate the clock display unit 5a are preset to be turned off.

  In addition, the meter unit 1 is provided with notifying means such as a disconnection warning light or a multiple display (not shown), and the CPU 12 has the tachometer light sources L21 to L28 and the odd-trip display light sources L51 to L5n. When this line is detected, the fact is displayed on a warning light of the meter or a multiple display to notify the passenger.

  Next, the operation of the meter unit 1 configured as described above will be described below with reference to FIGS. FIG. 7 is a flowchart showing a processing procedure of the CPU 12 shown in FIG. FIG. 8 is a flowchart showing details of the disconnection detection process shown in FIG. As shown in FIG. 7, the CPU 12 starts the process when the driver turns on the light switch, turns on all the light sources L, L21 to L28, L31 to L38, L41 to L4n, L51 to L5n, and the meter unit 1. Is illuminated (step S1).

  Next, the CPU 12 functions as disconnection detection means, and performs disconnection detection processing for detecting disconnection of the light sources L21 to L28 for the tachometer and the light sources L51 to L5n for the odd / trip display units (step S2). As shown in FIG. 8, in the disconnection detection process, the CPU 12 first substitutes 1 for m (step S201). Next, the connection point voltage Vc of the light source L2m for the tachometer is acquired from the A / D converter 20 (step S202), and it is determined whether or not the acquired connection point voltage Vc is substantially equal to the drive voltage VH (step S203). .

  Thereafter, when the CPU 12 determines that the connection point voltage Vc is substantially equal to the drive voltage VH (Y in step S203), the CPU 12 determines that the tachometer light source L2m is disconnected and sets a flag indicating that ( Step S204), the process proceeds to Step S205. On the other hand, if the CPU 12 determines that the connection point voltage Vc is small and not equal to the drive voltage VH (N in step S203), the CPU 12 determines that the light source L2m for the tachometer is not disconnected and proceeds to step S204 immediately without proceeding to step S204. The process proceeds to S205. In step S205, the CPU 12 increments m, and then determines whether m> 8 (step S206). If m> 8 is not satisfied (N in step S206), the CPU 12 determines that disconnection detection of all the tachometer light sources L21 to L28 has not been completed, and returns to step S21 again.

  On the other hand, if m> 8 (Y in step S206), the CPU 12 determines that the disconnection detection of all the light sources L21 to L28 has been completed, and then substitutes 1 for M (step S207). . Thereafter, the node voltage Vc of the odd-trip display light source L5M is taken in from the A / D converter 20 (step S208), and it is determined whether or not the fetched node voltage Vc is substantially equal to the drive voltage VH (step S208). S209).

  Thereafter, when the CPU 12 determines that the connection point voltage Vc is equal to the drive voltage VH (Y in step S209), the CPU 12 determines that the odd-trip display light source L5M is disconnected and sets a flag indicating that. (Step S210), the process proceeds to the next Step S211. On the other hand, if the CPU 12 determines that the connection point voltage Vc is small and not equal to the drive voltage VH (N in step S209), the CPU 12 determines that the odd / trip display light source L5M is not disconnected and does not proceed to step S210. The process immediately proceeds to step S211. In step S211, the CPU 12 increments M, and then determines whether M> n (step S212). If M> n is not satisfied (N in step S212), the CPU 12 determines that disconnection detection of all the odd-trip display light sources L51 to L5n has not been completed, and returns to step S208 again.

  On the other hand, if M> n (Y in step S212), the CPU 12 determines that the disconnection detection has been completed for all the light sources L51 to L5n for the odd / trip display units, and proceeds to step S3 in FIG. Next, when at least one disconnection flag is set and disconnection is detected by the disconnection detection process (Y in step S3), the CPU 12 functions as an extinguishing means and refers to the tables shown in FIGS. After the light source corresponding to the light source where the disconnection is detected is turned off (step S4), the process returns to step S2. On the other hand, if no disconnection is detected by the disconnection detection process (N in step S3), the CPU 12 immediately returns to step S2.

  According to the meter unit 1 described above, when the disconnection is detected by the disconnection detection process, the CPU 12 excludes the tachometer light sources L21 to L28 from which the disconnection is detected among the tachometer light sources L21 to L28. Since the light sources corresponding to the tachometer light sources L21 to L28 in which a predetermined disconnection is detected are turned off from among the tachometer light sources L21 to L28, even if the disconnection occurs, the display balance is prevented from being lost and the appearance is not deteriorated. .

  Specifically, according to the table shown in FIG. 5, the CPU 12 turns off the tachometer light source L28 when the tachometer light source L21 is disconnected, and turns off the tachometer light source L27 when the tachometer light sources L22 and L23 are disconnected. L28 is turned off. The CPU 12 does not turn off the other light sources L21 to L23 and L26 to L28 when the tachometer light sources L24 and L25 are disconnected. The CPU 12 turns off the tachometer light sources L23 to L21 when the tachometer light sources L26 to L28 are disconnected. That is, the CPU 12 extinguishes the tachometer light sources L21 to L28 arranged at line-symmetrical positions with respect to the tachometer light sources L21 to L28 in which the disconnection is detected. The display balance is not lost, so the appearance does not deteriorate.

  Further, according to the meter unit 1 described above, the CPU 12 detects the disconnection only when the tachometer light sources L21 to L28 are disconnected from the speedometer light sources L31 to L38 and the tachometer light sources L21 to L28. Since the tachometer light sources L21 to L28 corresponding to the tachometer light sources L21 to L28 are turned off, the speedometer light sources L31 to L38 for illuminating the speedometer 4b are not turned off, so the speedometer 4b indispensable for driving the vehicle. Can be prevented from becoming difficult to see.

  According to the meter unit 1 described above, the CPU 12 has the clock display unit 5a arranged in a line-symmetrical position with respect to the odd-trip display unit 5b illuminated by the light sources L51 to L5n for the odd-trip display unit in which disconnection is detected. The light sources L41 to L4n for illuminating the clock display unit are turned off. Specifically, the CPU 12 turns off the light sources L41 to L4n having the same number as the number of disconnections of the light sources L51 to L5n for the odd trip display units. Thereby, even if the disconnection occurs in the light sources L51 to L5n for the odd / trip display part and the odd / trip display part 5b becomes dark, the clock display part 5a also becomes dark, so that the display balance around the symmetry axis A1 is lost. There is no, it does not look bad.

  According to the meter unit 1 described above, the CPU 12 turns off only the clock display light sources L41 to L4n among the light sources L51 to L5n and the clock display light sources L41 to L4n, and displays the odd trip display. Since the light sources L51 to L5n for the sections are not turned off, the light sources L51 to L5n for the odo trip display section 5b that illuminate the odo trip display section 5b are not turned off even if the light sources L41 to L4n for the clock display section are disconnected. It is possible to prevent the odd trip display portion 5b essential for driving the vehicle from becoming difficult to see.

  According to the above-described embodiment, the disconnection detection is performed only for the tachometer light sources L21 to L2n and the odd-trip display light sources L51 to L5n, but the present invention is not limited to this. Disconnection detection of all the light sources L, L21 to L28, L31 to L38, L41 to L4n, and L51 to L5n provided in the meter unit 1 may be performed.

  In FIG. 1, the arrangement of each tachometer 4a, speedometer 4b, clock display unit 5a, and odd trip display unit 5b is an example, and other arrangements may be used.

  In the present embodiment, the tachometer 4a is used as the first display unit, but the present invention is not limited to this. The first display unit may be a display unit other than the speedometer 4b.

  Furthermore, in the present embodiment, the clock display unit 5a is the second display unit, but the present invention is not limited to this. As a 2nd display part, it is display parts other than the odd trip display part 5b, Comprising: What is necessary is just a display part arrange | positioned in the symmetrical position of the odd trip display part 5b.

  Further, the above-described embodiments are merely representative forms of the present invention, and the present invention is not limited to the embodiments. That is, various modifications can be made without departing from the scope of the present invention.

4a Tachometer (display unit, first display unit)
4b Speedometer (display unit)
5a Clock display unit (display unit, second display unit)
5b Odo trip display section (display section)
12 CPU (disconnection detection means, extinguishing means)
L light source L21 to L28 Light source for tachometer (light source, first display light source)
L31-L38 Speedometer light source (light source)
L41-L4n Light source for clock display part (light source, light source for second display part)
Light source (light source) for L51-L5n odd trip display

Claims (3)

In an illuminating device comprising: a plurality of light sources that illuminate the display unit; and a disconnection detection unit that detects disconnection of the plurality of light sources.
The plurality of light sources are arranged so as to be line-symmetric with respect to one display unit,
When disconnection is detected by the disconnection detection means, the apparatus further comprises an extinguishing means for turning off the light source arranged in a line symmetrical position with respect to the light source from which the disconnection is detected among the plurality of light sources . Lighting device. The display unit is provided with a plurality of speedometers and first display units other than the speedometer,
The plurality of light sources includes a plurality of speedometer light sources that illuminate the speedometer, and a plurality of first display unit light sources that illuminate the first display unit,
The light-off means is line-symmetric with respect to the first display light source in which the disconnection is detected only when the first display light source is disconnected from the speedometer light source and the first display light source . the lighting device according to claim 1, positioned to turn off the first display unit for light source arranged, a light source for the speedometer is characterized in that it does not turn off. The display unit is provided with a plurality of odd-trip display units arranged in line symmetry with each other, and a second display unit other than the odd-trip display unit,
The plurality of light sources are composed of a light source for an odo trip display unit that illuminates the odo trip display unit, and a light source for a second display unit that illuminates the second display unit,
The turning-off means turns off the second display light source only when the odd-trip display light source out of the odd-trip display light source and the second display light source is disconnected . The lighting device according to claim 1 or 2 , wherein when the light source for the display unit is disconnected, the light source for the odd-trip display unit is not turned off.

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