KR102322299B1 - Lighting device and control device thereof - Google Patents

Abstract

The present invention discloses a lighting device. The lighting device may include: an LED module having an LED channel; and a control unit including a memory having a user area and a chip area, and controlling the LED channel to be dimmed for each channel according to a preset value in the chip area, wherein the control unit includes a data interface between an external microcomputer and the memory. An interface is made so that transmission/reception is possible, and an interface is made so that access to the chip area is restricted.

Description

LIGHTING DEVICE AND CONTROL DEVICE THEREOF

The present invention relates to a lighting device, and more particularly, to a lighting device applicable to a lighting device for a vehicle and a control device thereof.

In general, a lighting device is a device for generating light, and a vehicle is provided with a lighting device for various purposes, and rear combination lamps installed at both sides of the rear of the vehicle may be included in the lighting device.

The rear combination lamp includes a direction indicator lamp, a braking lamp, a tail lamp, a reverse lamp, and the like, and is used as a means to notify the driver of another vehicle following from the rear of the driving intention and driving state of the vehicle.

Recently, with the rapid development of a high-brightness LED (Light Emitted Diode), a rear combination lamp and a head lamp employing an LED are being developed. The design of rear combination lamps employing LEDs as light sources is diversifying, and the number of LEDs used is also increasing.

However, the lighting device using the LED as described above has a limit in increasing the number of parts controlling the light emission of the LED in proportion to the increase in the number of LEDs, and there is a limit in uniformly disposing the LEDs according to the installation environment of the vehicle. As a result, a difference in the amount of light may occur for each location.

A lighting device according to the prior art drives a lamp using an FET or a BJT and an OP-AMP. In the prior art as described above, there may be a limit to the increase of the L-CH channel depending on the installation environment of the vehicle, and errors may occur in the offset between parts and the arrangement of parts.

The error between the components as described above may cause a current deviation between LED channels, and the conventional technique may not be able to perform uniform brightness control between channels due to the current deviation.

In addition, in order to satisfy market trends and emotional satisfaction that require various functions, it is impossible to simply use ON and OFF functions. In particular, in the case of a rear combination lamp that lights up in various forms depending on the situation, a more complex design is required.

Accordingly, there is an urgent need for a technology capable of lighting the rear combination lamp in various forms by accurately controlling the channel current with a target current despite the increase in the number of LED channels.

Meanwhile, as a device for storing data, there may be a magnetic disk, a semiconductor memory, or the like. Recently, non-volatile memory (NVM), which has a shorter read/write time compared to magnetic disks, consumes less power, and occupies a small volume, is rapidly replacing magnetic disks.

The non-volatile memory is a semiconductor memory device capable of electrically reading, writing, and erasing, and maintaining stored data even in the absence of a power supply. In addition to writing, the process of storing data in the non-volatile memory is also called programming.

Unlike magnetic disks, non-volatile memory is not overwritten, so it must be erased before data is written. When using the integrated circuit (IC) for controlling the rear combination lamp, the data for controlling the LED channel must be protected.

However, if the customer can access the memory in which the data for controlling the LED channel that is not disclosed by mistake or intentionally and can erase and write the nonvolatile memory, there is a possibility of loss of the data for controlling the LED channel.

The technical problem to be solved by the present invention is to provide a lighting device capable of restricting access to an address of a memory in which data for controlling an LED channel is set, and a control device thereof.

Another technical problem to be solved by the present invention is to provide a lighting device capable of stably lighting a plurality of LED channels with a target channel current in spite of applying them to the lighting of a vehicle, and a control circuit thereof.

Another technical problem to be solved by the present invention is to provide a lighting device capable of illuminating a plurality of LED channels in various forms through dimming control for each channel, and a control circuit thereof.

The lighting device of the present invention includes: an LED module having an LED channel; and a control unit including a memory having a user area and a chip area, and controlling the LED channel to be dimmed for each channel according to a preset value in the chip area, wherein the control unit includes a data interface between an external microcomputer and the memory. An interface is made so that transmission/reception is possible, and an interface is made so that access to the chip area is restricted.

A lighting device of the present invention, a lamp having an LED channel; and a control unit that temporarily stores data provided from a microcomputer in a register, and controls dimming for each channel of the LED channel in response to the data stored in the register.

A control apparatus for a lighting device of the present invention includes: a memory including a user area to which access is allowed and a chip area to which access is restricted, and storing data for driving a controller and controlling an LED channel in the chip area; a register for temporarily storing data read from the memory and data provided from a microcomputer; and a communication module that interfaces to enable data transmission/reception between the microcomputer and the memory, and restricts or permits address access of the chip area.

The present invention controls the dimming of the LED channels for each channel according to a preset value in the memory, so that a plurality of LED channels can be stably lit with a target channel current, and the LED channels can be lit in various forms.

The present invention divides the memory into a user area and a chip area, stores data for chip driving and LED channel control in the chip area, restricts access to the chip area through a specific bit of an address, and restricts access through a lock release code It can prevent data loss due to customer error or environmental factors.

1 is a block diagram illustrating an embodiment of a lighting device of the present invention.
FIG. 2 is a block diagram illustrating a configuration of a control unit of FIG. 1 .
FIG. 3 is a waveform diagram for explaining a signal of the communication module of FIG. 2 .
4 and 5 are block diagrams illustrating access restrictions of the chip area IC of FIG. 2 .
6 and 7 are tables illustrating reading, writing, and erasing in the memory and register of FIG. 2 .

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms used in the present specification and claims are not limited to a conventional or dictionary meaning, and should be interpreted in a meaning and concept consistent with the technical matters of the present invention.

The configuration shown in the embodiments and drawings described in this specification is a preferred embodiment of the present invention, and does not represent all of the technical spirit of the present invention, so various equivalents and modifications that can be substituted for them at the time of the present application are provided. there may be

1 is a block diagram illustrating an embodiment of a lighting device of the present invention. This embodiment can be applied to a lighting device of a vehicle, and FIG. 1 shows that it is applied to a rear combination lamp RCL among lighting devices of a vehicle.

Referring to FIG. 1 , this embodiment includes a rear combination lamp (RCL), a converter 10 , a controller 20 , and a microcomputer 40 .

The rear combination lamp RCL includes an LED module 50 having an LED channel, the LED module 50 includes one or more LED channels, and a plurality of LED channels may be configured in parallel. 1 illustrates that one control unit 20 drives the LEDs of the first to eighth channels CH1 to CH8 of the LED module 50 .

The vehicle controller 30 controls the battery voltage VB to be transmitted to the converter 10 in response to at least one of a direction indication signal, a sudden braking signal, a braking signal, and a tail signal, and dims in response to the sudden braking signal or the braking signal. The signal DIM is controlled to be transmitted to the controller 20 .

The converter 10 generates an output voltage VOUT and an internal voltage VIN using the battery voltage VB supplied from the vehicle control unit 30, and supplies the output voltage VOUT to the LED module 50, The internal voltage VIN is supplied to the control unit 20 . As an example, the converter 10 may be a buck converter.

The control unit 20 may be configured as a single semiconductor chip, and when the internal voltage VIN is supplied from the converter 10, the memory 24 corresponds to the logic state of the dim signal DIM, as shown in FIG. 2 . ) turns on or blinks the first to eighth channels CH1 to CH8 of the LED module 50 through preset values. The control unit 20 controls the feedback voltage terminals FB1 to FB8 to which the first to eighth channels CH1 to CH8 are connected, respectively, and the channel resistor terminals RCH1 to RCH8 to which the channel resistors R1 to R8 are respectively connected. have The control unit 20 may include a switching unit therein, and the switching unit may be configured to form or block a current path between each feedback voltage terminal FB1 to FB8 and each channel resistance terminal RCH1 to RCH8. .

The controller 20 controls the output voltage VOUT of the converter 10 to be adjusted in response to the feedback voltages FB1 to FB8 of the first to eighth channels CH1 to CH8. The controller 20 may detect a minimum feedback voltage among the feedback voltages FB1 to FB8 and adjust the output voltage VOUT to adjust the minimum feedback voltage to a target feedback voltage. As described above, the control unit 20 stably supplies the output voltage VOUT to the first to eighth channels CH1 to CH8 despite variations in the battery voltage VB transmitted from the vehicle control unit 30 or variations in load. The converter 10 is controlled so that it can be In addition, the controller 20 controls the switching element (eg, FET/BJT) so that the channel currents ILED1 to ILED8 of the first to eighth channels CH1 to CH8 can be adjusted in response to a preset memory value. do. The switching element may be configured inside or outside the control unit 20 . The present embodiment is configured to embed the switching element therein, but is not limited thereto.

VIN shown in FIG. 1 is an internal voltage for the operation of the control unit 20, SEN is a sensing voltage used for level determination and counting synchronization of the internal voltage VIN, and GATE is an internal voltage for regulating the output voltage VOUT. control signal. The GATE may be provided as a PWM (Pulse Width Modulation) signal.

As such, the control unit 20 turns on or blinks the first to eighth channels CH1 to CH8 of the LED module 50 through values set in the memory 24 in response to the logic state of the dim signal DIM. Values set in the memory 24 may be set differently for each channel in response to the state of the dim signal DIM. For example, at least one of brightness for each channel, delay between channels, lighting order between channels, duty for each channel, channel use/non-use determination, current for each channel, and reference voltage may be set.

The memory 24 may be configured using internal or external memory, and in the case of multi-type programmable (MTP) among internal memories, non-volatile memory (NVM), electrically erasable programmable read-only memory (EEPROM), etc. This can be used.

Non-volatile memory can be electrically read, written, and erased, and stored data can be maintained even when there is no power supply. These non-volatile memories must be erased before writing. In this case, there may be a possibility of data loss due to external environmental factors or a customer's mistake.

The present invention divides the memory 24 into a user area (USER) and a chip area (IC), and restricts access to the chip area (IC) in which data for chip driving and LED channel control is set through a specific bit of an address, and lock An object of the present invention is to provide a lighting device capable of releasing the access restriction of the chip area IC through a release code and a control device thereof. Referring to FIG. 2 , the control unit 20 of the present embodiment includes the communication module 22 and the memory ( 24), and a register 26 .

The communication module 22 interfaces to enable data transmission/reception between the external microcomputer 40 and the memory 24 . Specifically, the communication module 22 interfaces so that data transmission and reception is possible between the microcomputer 40 and the memory 24 and the register 26, and interfaces so that address access of the chip area IC of the memory 24 is restricted. do. Here, the microcomputer 40 and the control unit 20 may be configured to communicate through at least one of a wired communication protocol and a wireless communication protocol.

In this embodiment, the microcomputer 40 and the control unit 20 are configured to communicate through SPI (Serial Peripheral Interface), but LIN (Local Interconnect Network), CAN (Controller Area Network), and arbitrarily promised protocol ( Protocol) can be configured to communicate through at least one.

The microcomputer 40 and the control unit 20 are connected through the CSN, SCL, SDI, and SDO pins of the communication module 22 .

2 and 3 , the CSN pin is used to select the control unit 20 . 1 illustrates only one control unit 20, the lighting device may include a plurality of control units according to the number of LED channels employed in the rear combination lamp or the installation environment of the vehicle. At this time, at least one of the plurality of controllers is selected according to the signal of the CSN pin. For example, when the signal of the CSN pin is in a low level state, the microcomputer 40 and the controller 20 can transmit and receive data.

The SCL pin is used for transmitting a clock signal necessary for data transmission, the SDI pin is used for the microcomputer 40 to transmit data to the communication module 22 of the control unit 20, and the SDO pin is used for transmitting the data of the control unit 20. A communication module 22 is used to transmit data to the microcomputer 40 .

Referring to FIG. 3 , when the signal of the CSN pin is in a low level state, the microcomputer 40 and the controller 20 are in a state in which data transmission and reception are possible. The microcomputer 40 provides a clock signal to the control unit 20 through the SCL pin, provides an address and data to the control unit 20 through the SDI pin in synchronization with the clock signal, and receives data through the SDO pin . 3 exemplifies 16 bits, 2 bits of the 16 bits are loaded with operation types of read, write, and erase, 6 bits are addresses, and 8 bits are data loaded and provided to the control unit 20 .

The register 26 of the control unit 20 temporarily stores addresses and data provided from the microcomputer 40 or data read from the memory 24 . As the register 26, a shift register may be used.

The memory 24 of the controller 20 is divided into a user area USR where access is allowed and a chip area IC where access is restricted. The division of the user area USR and the chip area IC may be divided in units of banks or addresses. The chip area IC is set to restrict access according to the logic state of a specific bit of the address, and the controller 20 interfaces to release the access restriction to the chip area IC when a lock release code is input.

Data for driving the controller 20 and controlling the LED channel may be set in the chip region IC. For example, the brightness of each of the first to eighth channels (CH1 to CH8) of the LED module 50, delay between channels, lighting sequence between channels, duty for each channel, channel use/non-use determination, current for each channel, reference voltage, etc. A dimming setting value for each LED channel and an option for driving the control unit 20 may be set.

4 and 5 , the communication module 22 of the control unit 20 limits address access of the chip area IC in response to the logic state of a specific bit of the chip area IC, and inputs a lock release code Interface so that the lock is released in response. For example, if the logic of a specific bit of the address of the chip area (IC) is 'high', it is in the lock-on state, and if the logic of the specific bit is 'low', it is in the lock-off state, and the unlock code is is input, the lock-on state is converted to the lock-off state. In this way, the present embodiment can restrict address access of the chip area IC.

Referring to FIG. 6 , in the present embodiment, a specific bit among the address bits is set to '1' to restrict address access of the chip area IC. In FIG. 6 , an 8th bit among bits 0 to 15 is used as a bit for restricting access to the chip area IC, but a bit for restricting access to the chip area IC uses a single bit or a plurality of bits to the chip area. (IC) can be set to restrict access. In FIG. 6 , a read command corresponds to HEX code A1C3, a write command corresponds to A1B3, an erase command corresponds to A1A3, and a lock release code corresponds to A15E.

Referring to FIG. 7 , in the present embodiment, commands for the user area USR and the chip area IC may be separated and configured differently. For example, the read command and unlock code of the user area (USR) and the chip area (IC) may be set identically to A1C3 and A15E, respectively, but the erase and write commands of the user area (USR) are A2XX and A2XX, respectively. is set, and the erase and write commands of the chip area IC may be set differently to ABXX and ACXX, respectively. As described above, the present embodiment can be configured differently by separating the erase and write commands of the user area USR and the chip area IC.

As described above, in this embodiment, the erase and write commands for address access in the user area USR and the chip area IC are configured separately, so that the chip set in the chip area IC due to the customer's mistake and environmental factors. It prevents data for driving and controlling the LED channel from being lost.

Meanwhile, since the memory cell has a limited number of writing and erasing, a backup cell may be provided for some or all of the memory cells that are expected to be frequently changed. For example, if the brightness value of the first channel (CH1) is set at address 00, when the brightness value of the first channel (CH1) is written and erased several times and its life is expired, address 00 can be replaced with address 01 have. In order to implement this, it can be configured to automatically change the address when a set target number is reached by counting each time of writing and erasing.

The microcomputer 40 may be configured as a microcontroller unit (MCU). The controller 20 may be controlled in response to a data signal provided from the microcomputer 40 .

The microcomputer 40 may be linked with the vehicle's ECU (not shown), and may be configured to provide a value for controlling each LED channel to the control unit 20 in response to an event signal provided from the vehicle's ECU. . For example, the microcomputer 40 turns on/off the LED channel, the on/off delay value between the LED channels, the current change between the LED channels (dimming duty, etc.), the on/off order between the LED channels, the use/non-use decision of the LED channel etc. are provided to the register 26 of the control unit 20, and the control unit 20 uses the value stored in the register 26 through the first to eighth channels of the LED module 50 of the rear combination lamp RCL. (CH~CH8) is controlled to be driven.

In this case, the controller 20 does not change the set value of the chip area IC, but controls the first to eighth channels CH to CH8 to be dimmed for each channel with a value provided from the microcomputer 40 .

For example, when the door lock of the vehicle is released, the ECU (not shown) of the vehicle provides an event signal to the microcomputer 40, and the microcomputer 40 controls each LED channel in response to the event signal provided from the ECU. A value for is provided to the control unit 20 .

The control unit 20 turns on or blinks a plurality of LED channels in response to a value provided from the microcomputer 40 . The event signal may be an open signal of a vehicle door, an approach signal of a smart key, and the like. However, the present invention is not limited thereto. The value provided from the microcomputer 40 may be set to at least one of an on-off delay value between LED channels, a current value between LED channels, an on-off sequence between LED channels, use/non-use of LED channels, and the like.

As such, in this embodiment, the control unit 20 is configured to be linked through the external microcomputer 40 and the communication module 22, and the rear combination lamp (RCL) corresponding to the value provided from the microcomputer 40 lighting can be controlled.

As described above, in the present invention, since the LED channel is controlled to be dimmed for each channel according to a value preset in the memory, it is possible to stably light the LED channel with a target channel current despite applying a plurality of LED channels to the rear combination lamp, and the rear Combination lamps can be lit in various forms.

The present invention restricts access to the chip area (IC) of a memory in which data for driving a chip and LED channel control is stored through a specific bit, releases access to the chip area (IC) through a lock release code, and a user area (USR) Since the commands of the chip area (IC) are separated and configured differently, data loss due to customer mistakes or environmental factors can be prevented.

10: converter 20: control unit
30: vehicle control unit 40: microcomputer
50: LED module RCL: rear combination lamp
22: communication module 24: memory
26: register

Claims (15)

an LED module having LED channels; and
A control unit comprising a memory having a user area and a chip area, and controlling dimming of each of the LED channels in response to a preset value in the chip area
including,
The control unit controls data transmission/reception between an external microcomputer and the memory, restricts access to the chip area, and separates erase and write commands for the user area and the chip area and is set differently, lighting device . According to claim 1, wherein the control unit
A lighting device configured to restrict access to the chip region in response to a logic state of a specific bit among the address bits of the memory. 3. The method of claim 2,
The control unit is set to release the access restriction of the chip area by the specific bit in response to the unlock code. 3. The method of claim 2,
The specific bit is a lighting device in which a single bit or a plurality of bits of the address of the memory are preset. delete According to claim 1, wherein the control unit
a communication module controlling data transmission/reception between the microcomputer and the memory and restricting access to the chip area;
a memory including the user area to which access is allowed and the chip area to which access is restricted; and
a register for temporarily storing data provided from the microcomputer or data read from the memory;
A lighting device comprising a. According to claim 1, wherein the chip region
At least one of the driving data of the controller and the data for controlling the LED channel is set in advance. lamps with LED channels; and
A control unit that temporarily stores data provided from a microcomputer in a register, and controls dimming of each of the LED channels in response to the data stored in the register
including,
The control unit is a lighting device, in which the erase and write commands for the user area and the chip area are respectively set differently. The method of claim 8, wherein the control unit
A lighting device configured to receive a clock signal from the microcomputer and to receive the data synchronized with the clock signal. The method of claim 8, wherein the control unit
A lighting device set to receive at least one of the data for driving of the controller and data for controlling the LED channel from the microcomputer. The method of claim 8, wherein the microcomputer
A lighting device connected to an ECU of a vehicle and configured to provide the data to the control unit in response to an event signal provided from the ECU. a memory including a user area to which access is permitted and a chip area to which access is restricted, and for storing driving data of a controller and data for dimming control of LED channels in a chip bank;
a register for temporarily storing data read from the memory and data provided from a microcomputer; and
A communication module that controls data transmission/reception between the microcomputer and the memory, and restricts or permits address access of the chip area
including,
The user area and the chip area are respectively set differently by erasing and writing commands. 13. The method of claim 12, wherein the communication module
A control device of a lighting device configured to receive an address and data from the microcomputer and restrict or allow address access of the chip region in response to a logic state of a specific bit of the address. 13. The method of claim 12,
The communication module is a control device of a lighting device set to release the access restriction of the chip area by a specific bit in response to the unlock code. delete

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