JP7183012B2 - Vehicle lamp and its lighting circuit - Google Patents

Description

The present invention relates to a vehicle lamp used in automobiles and the like.

Dimming is one of the important functions of a lamp. Semiconductor light sources such as LEDs (Light Emitting Diodes) have been adopted in recent lighting fixtures, and dimming methods for semiconductor light sources can be broadly divided into analog dimming (linear dimming) and PWM (Pulse Width Modulation) dimming. Analog dimming adjusts the DC level of the drive current flowing through the semiconductor light source. PWM dimming adjusts the average level of the drive current by switching the current flowing through the semiconductor light source and adjusting the ratio of the ON period.

Lighting circuits for semiconductor light sources are classified into those using a DC/DC converter and those using a linear regulator (series regulator). The former is highly efficient, but the cost is high. Therefore, the linear regulator is adopted for lamps requiring low cost.

FIG. 1 is a block diagram of a lamp having a linear regulator (series regulator). The lamp 100R includes a light source 110 and a lighting circuit 200R. Light source 110 includes one or more light emitting elements 112 . The lighting circuit 200R receives the power supply voltage _VDD from the battery, and stabilizes the drive current (lamp current) _ILAMP flowing through the light source 110 to a current amount corresponding to the target luminance. The lighting circuit 200R includes a linear regulator 210 and a switch SW for PWM dimming.

Linear regulator 210 includes output transistor 212, resistor R1 and error amplifier (op amp) 214, and regulates lamp current I _LAMP to a current amount I _REF that varies linearly with reference voltage V _ADIM ).
I _REF = (V _DD -V _ADIM )/R (1)

The switch SW is provided between the gate of the output transistor 212 and the power supply line 102 (or between the gate and source). During the period in which the switch SW is off, the lamp current _{I_AMP} of the target amount _{I_REF} of the formula (1) flows, and the light source 110 is lit (lighting period). While the switch SW is on, the output transistor 212 is turned off, the lamp current _ILAMP becomes zero, and the light source 110 is extinguished (extinction period).

By switching the switch SW in a predetermined PWM cycle according to the control signal _SPWM for PWM dimming, the lighting period and the lighting-out period alternately occur. Therefore, when the duty ratio of the control signal S _PWM is changed, the average amount of the lamp current _ILAMP flowing through the light source 110 is changed, and the effective brightness of the light source 110 is changed.

FIG. 2 is an operating waveform diagram of the lamp 100R of FIG. When the power supply voltage _VDD is input at time _t0 , the lighting circuit 200R is activated. Between times t ₀ and t ₁ , the duty ratio of the PWM signal S _PWM is 100% (that is, fixed at high level), and the lamp current I _LAMP is stabilized at the target amount I _REF .

After time t ₁ , PWM dimming (also referred to as PWM dimming) is turned on to dim the light source 110 . Specifically, the duty ratio d of the PWM signal S _PWM decreases (50% in this example). As a result, the lamp current I _LAMP becomes I _REF during the lighting period T _ON and 0 A during the extinguishing period T _OFF , and the average value becomes I _LAMP(AVE) =I _REF ×d.

When the power supply voltage V _DD is cut off at time _t2 , the lighting circuit 200R stops and the lamp current I _LAMP becomes zero.

International publication WO2017/150322

The lighting fixture 100R employing a linear regulator has the advantage of less electromagnetic noise than a lighting fixture using a DC/DC converter. However, when PWM dimming is performed as described above, electromagnetic noise is generated due to switching of the lamp current _ILAMP .

SUMMARY OF THE INVENTION The present invention has been made in view of these problems, and one of the exemplary objects of certain aspects thereof is to provide a vehicle lamp and its lighting circuit that can reduce electromagnetic noise or can easily take countermeasures against it. .

One aspect of the present invention is a lighting circuit for a semiconductor light source. The lighting circuit has a duty ratio corresponding to the input pulse signal and generates a dimming signal in which at least one edge is dull. a linear regulator that stabilizes to the target amount.

Since the waveform of the lamp current changes based on the waveform of the dimming signal, by blunting the waveform of the dimming signal, steep changes in the lamp current can be suppressed, electromagnetic noise can be reduced, or countermeasures can be easily taken. becomes.

The dimming circuit may include a capacitor and a charge/discharge circuit that charges and discharges the capacitor according to the pulse signal, and the dimming signal may correspond to the voltage of the capacitor. By limiting at least one of the charging and discharging speeds, a dimming signal with dull edges can be generated.

The charging/discharging circuit includes a first switch and a first resistor provided in series between one end of the capacitor and a reference voltage line, and a second switch provided between one end of the capacitor and a ground line, the first switch and the second switch may complementarily switch in response to the pulse signal. In this case, the positive edge of the dimming signal can be dulled according to the resistance value of the first resistor.

The charge/discharge circuit may further include a second resistor provided in series with the second switch between one end of the capacitor and the ground line. In this case, the negative edge of the dimming signal can be dulled according to the resistance value of the second resistor.

The charging/discharging circuit includes a first switch provided between one end of the capacitor and the reference voltage line, and a second switch and a second resistor provided in series between one end of the capacitor and the ground line, the first switch and the second switch may complementarily switch in response to the pulse signal. In this case, the negative edge of the dimming signal can be dulled according to the resistance value of the second resistor.

The charging/discharging circuit includes a first current source provided between one end of the capacitor and the reference voltage line, and a second current source provided between one end of the capacitor and the ground line. A current source may be complementarily turned on in response to the pulse signal. In this case, the waveform of the dimming signal can be dulled by decreasing the current supply capability of at least one of the first current source and the second current source (increasing the output impedance).

The charge/discharge circuit may include a driver that outputs a high voltage and a low voltage according to the pulse signal, and a resistor provided between the output of the driver and one end of the capacitor. A low-pass filter formed by a resistor and a capacitor can dull the output signal of the driver.

The lighting circuit may further include a third switch provided between one of the power supply line and the ground line and the gate of the output transistor of the linear regulator. By turning on the third switch, it is possible to reliably cut off the lamp current even when there is an offset voltage in the operational amplifier of the linear regulator.

Arbitrary combinations of the above constituent elements, and mutual replacement of the constituent elements and expressions of the present invention between methods, devices, systems, etc. are also effective as aspects of the present invention.

ADVANTAGE OF THE INVENTION According to the aspect of this invention, electromagnetic noise can be suppressed or countermeasures against electromagnetic noise can be facilitated.

1 is a block diagram of a lamp with a linear regulator; FIG. FIG. 2 is an operation waveform diagram of the lamp of FIG. 1; 1 is a block diagram of a lamp system including the lamp according to Embodiment 1; FIG. 4 is an operation waveform diagram of the lamp of FIG. 3; FIG. 5(a) and 5(b) are circuit diagrams showing configuration examples of the dimming circuit. FIG. 6 is an operation waveform diagram of the dimming circuit of FIG. 5(b); FIGS. 7A and 7B are circuit diagrams showing other configuration examples of the dimming circuit. FIG. 10 is a block diagram of a lamp system according to Embodiment 2; FIG. FIGS. 9A to 9D are diagrams showing an LED socket as an example of a lamp. FIG. 11 is a block diagram of a lighting system including a lighting fixture according to Embodiment 3; 11 is an operation waveform diagram of the lamp system of FIG. 10; FIG. FIG. 11 is a block diagram of a lamp system including a lamp according to Embodiment 4; 13 is an operation waveform diagram of the lamp system of FIG. 12; FIG. FIG. 11 is a block diagram of a lamp system including a lamp according to Embodiment 5; 15 is an operation waveform diagram of the lamp system of FIG. 14; FIG. FIG. 10 is a circuit diagram of a lamp according to Modification 1; FIG. 11 is a circuit diagram of part of a lighting circuit according to Modification 2;

BEST MODE FOR CARRYING OUT THE INVENTION The present invention will be described below based on preferred embodiments with reference to the drawings. The same or equivalent constituent elements, members, and processes shown in each drawing are denoted by the same reference numerals, and duplication of description will be omitted as appropriate. Moreover, the embodiments are illustrative rather than limiting the invention, and not all features and combinations thereof described in the embodiments are necessarily essential to the invention.

In this specification, "a state in which member A is connected to member B" refers to a case in which member A and member B are physically directly connected, as well as a case in which member A and member B are electrically connected to each other. It also includes the case of being indirectly connected through other members that do not substantially affect the physical connection state or impair the functions and effects achieved by their combination.

Similarly, "the state in which member C is provided between member A and member B" refers to the case where member A and member C or member B and member C are directly connected, as well as the case where they are electrically connected. It also includes the case of being indirectly connected through other members that do not substantially affect the physical connection state or impair the functions and effects achieved by their combination.

Also, in this specification, the symbols attached to electrical signals such as voltage signals and current signals, or circuit elements such as resistors and capacitors, refer to respective voltage values, current values, resistance values, and capacitance values as necessary. shall be represented.

(Embodiment 1)
FIG. 3 is a block diagram of the lamp system 2 including the lamp 100 according to the first embodiment. The lighting system 2 includes a battery 4 , a switch 6 and an ECU (Electronic Control Unit) 8 . The power supply terminal VDD of the lamp 100 is supplied with the power supply voltage _VDD from the battery 4 via the switch 6 . The switch 6 is controlled according to a command to turn on/off the lamp 100 .

The lamp 100 has a light source 110 and a lighting circuit 200 . Light source 110 includes a plurality of light emitting elements 112 connected in series. Light-emitting element 112 is preferably an LED, but may be other semiconductor light-emitting elements such as LDs (laser diodes) or organic EL elements.

The lighting circuit 200 supplies a drive current (lamp current) _ILAMP to the light source 110 and controls the lamp current _ILAMP to adjust the luminance of the light source 110 .

The lighting circuit 200 has a constant current circuit 220 and a dimming circuit 240 . Constant current circuit 220 includes a linear regulator 210 and stabilizes lamp current I _LAMP flowing through light source 110 to target amount I _REF according to dimming signal V _ADIM .

Linear regulator 210 includes resistor R1, output transistor 212, and error amplifier (op-amp) 214, as described with reference to FIG. When the voltage input to the non-inverting input terminal (+) of the error amplifier 214 is V _ADIM ', the target amount I _REF of the lamp current I _LAMP is given by equation (2).
I _REF =(V _DD -V _ADIM ')/R1 (2)

Constant current circuit 220 includes V/I converter 230 and resistor R3 in addition to linear regulator 210 . A V/I converter 230 converts the dimming signal V _ADIM to a proportional current I _ADIM . When the conversion gain (conductance) is k, the current I _ADIM is expressed by Equation (3).
_IADIM =k× _VADIM (3)

Although the configuration of V/I converter 230 is not particularly limited, V/I converter 230 of FIG. In this case, the conversion gain k is represented by Equation (4).
k=1/R2 (4)

A voltage V _ADIM ' at a connection node between the V/I converter 230 and the resistor R3 is expressed by Equation (5).
_VADIM '= _VDD -R3× _IADIM (5)
By substituting equations (3) and (4) into equation (5), equation (6) is obtained.
V _ADIM ′=V _DD −R3×k×V _ADIM
=V _DD -R3/R2×V _ADIM (6)

By substituting equation (6) into equation (2), the input/output characteristics of constant current circuit 220 can be obtained and expressed by equation (7).
I _REF =R3/(R1·R2)×V _ADIM (7)

A pulse signal S _PWM for PWM dimming generated by the ECU 8 is input to a dimming (PWM) terminal of the lamp 100 . The pulse signal S _PWM has a duty ratio d corresponding to the target luminance (light reduction rate) of the light source 110 .

The pulse signal S _PWM is supplied to the dimming circuit 240 . The dimming circuit 240 generates a dimming signal V _ADIM having a duty ratio d corresponding to the pulse signal S _PWM and having at least one edge dull.

The above is the configuration of the lamp 100 . Next, the operation will be explained.
FIG. 4 is an operation waveform diagram of the lamp 100 of FIG. At time _t0 , the switch 6 is turned on, the power supply voltage _VDD is supplied to the lamp 100, and the lighting circuit 200 is activated. Between times t ₀ and t ₁ , the duty ratio of the PWM signal S _PWM is 100% (that is, fixed at high level). The analog dimming signal V _ADIM becomes a DC signal and the lamp current I _LAMP is stabilized to the target amount I _REF .

After time _t1 , the duty ratio d of the PWM signal S _PWM is set to 50% in order to dim the light source 110 . A dimming circuit 240 generates an analog dimming signal V _ADIM based on the PWM signal S _PWM . The analog dimming signal V _ADIM has the same duty ratio d as the PWM signal S _PWM , but its edges (both positive and negative edges in this example) are blunted. As a result, the lamp current _ILAMP generated by the constant current circuit 220 also has a blunted waveform.

When the switch 6 is turned off at time _t2 to cut off the power supply voltage _VDD , the lighting circuit 200 stops and the lamp current _ILAMP becomes zero.

The above is the operation of the lamp 100 . Since the waveform of the lamp current I _LAMP changes based on the waveform of the dimming signal V _ADIM , sharp changes in the lamp current _ILAMP can be suppressed by dulling the waveform of the dimming signal V _ADIM . This makes it possible to reduce the electromagnetic noise, or facilitate countermeasures against it.

Next, some configuration examples of the dimming circuit 240 will be described.

5A and 5B are circuit diagrams showing a configuration example (240A) of the dimming circuit 240. FIG. A dimming circuit 240A of FIG. The capacitor C11 has one end grounded and the other end connected to the output of the charging/discharging circuit 242 . The charging/discharging circuit 242 charges/discharges the capacitor C11 according to the pulse signal _SPWM . Dimming signal V _ADIM is responsive to voltage V _C11 developed across capacitor C11.

Charge/discharge circuit 242 includes, for example, a buffer (or inverter) intentionally designed to have high output impedance Ro. A reference voltage V _REF is applied to the power supply terminal of the final stage of the buffer (inverter). The reference voltage V _REF defines the high level of the voltage V _C11 of the capacitor C11, and analog dimming can be achieved by varying the reference voltage V _REF .

FIG. 5(b) is a specific configuration example of the dimming circuit 240A of FIG. 5(a). The charge/discharge circuit 242 is a buffer including two stages of inverters 244 and 246 connected in series. The preceding inverter 244 logically inverts the pulse signal S _PWM . A reference voltage V _REF is applied to the power supply terminal 242A of the inverter 246 in the latter stage. Between the power supply terminal 242A and the output terminal 242B of the inverter 246, a PMOS transistor (high side transistor) M11 and a resistor Ro1 are provided in series. Between the ground terminal 242C and the output terminal 242B of the inverter 246, an NMOS transistor (low-side transistor) M12 and a resistor Ro2 are provided in series.

FIG. 6 is an operation waveform diagram of the dimming circuit 240A of FIG. 5(b). The pulse signal S _PWM is inverted by the inverter 244 to generate the inverted pulse signal .omega.S _PWM . ￢ indicates logical inversion and is indicated by a bar in the drawing. Capacitor C11 is charged (discharged) with a time constant determined by its capacitance and resistance Ro1 (Ro2). As a result, the voltage V _C11 of the capacitor C11, that is, the dimming signal V _ADIM has a dulled waveform of the pulse signal S _PWM .

In this example, both the positive edge and the negative edge of the dimming signal V _ADIM are dulled, but only one of them may be dulled, in which case one of the resistors Ro1 and Ro2 can be omitted.

According to the dimming circuit 240A of FIG. 5B, the charging speed and discharging speed of the capacitor C11 can be set according to the resistors Ro1 and Ro2. Instead of omitting the resistors Ro1 and Ro2, the size of the transistors M11 and M12 may be reduced, and the charging/discharging speed may be lowered by the ON resistance.

7A and 7B are circuit diagrams showing other configuration examples (240B, 240C) of the dimming circuit 240. FIG. The dimming circuit 240B of FIG. 7A includes a buffer (or inverter) 250 and a low-pass filter 252. FIG. The dimming signal V _ADIM has a waveform obtained by blunting the output S _PWM ′ of the buffer 250 .

The dimming circuit 240C of FIG. 7(b) comprises current sources 254, 256 and a capacitor C31. The current sources 254, 254 can be switched on and off, and are switched complementarily according to the pulse signal S _PWM . As a result, the capacitor C31 is alternately charged and discharged. The voltage V _C31 of the capacitor C31 changes with a slope corresponding to the currents I1 and I2 generated by the current sources 254 and 256, and can gradually change the dimming signal V _ADIM .

(Embodiment 2)
In Embodiment 1, the ECU 8 generates the pulse signal S _PWM , but this is not the only option, and the pulse signal S _PWM may be generated inside the lamp 100D. FIG. 8 is a block diagram of a lamp system 2D according to the second embodiment. The lamp 100D has a control terminal (CNT). The ECU 8 supplies the CNT terminal with a control signal S _CTRL that designates the luminance or lighting mode of the light source 110 . It does not matter whether the control signal S _CTRL is an analog signal or a digital signal.

The lighting circuit 200</b>D includes a pulse generator 260 in addition to the constant current circuit 220 and the dimming circuit 240 . The pulse generator 260 generates a pulse signal S _PWM having a duty ratio according to the control signal S _CTRL . Dimming circuit 240 dampens pulse signal S _PWM generated by pulse generator 260 to generate dimming signal V _ADIM .

According to the second embodiment, as in the first embodiment, the electromagnetic noise of the lamp system 2C can be reduced, or countermeasures can be easily taken.

Next, the application of the lamp 100 will be described. The lighting fixture 100 may be, for example, a stop lamp, a tail lamp, or a turn signal lamp, and the light source 110 may be a red LED or an amber LED. A preferred aspect of the lamp 100 is an LED socket in which the light source 110 and the lighting circuit 200 are housed in one package, and has a shape that can be attached to and detached from the lamp body.

9A to 9D are diagrams showing an LED socket 700 as an example of the lamp 100. FIG. FIG. 9A is a perspective view of the appearance of the LED socket 700. FIG. 9B shows a front view of the LED socket 700, FIG. 9C shows a plan view of the LED socket 700, and FIG. 9C shows a bottom view of the LED socket 700. FIG.

The housing 702 has a shape that can be attached to and detached from a lamp body (not shown). A plurality of light emitting elements 706 are mounted in the central portion and covered with a transparent cover 704 . Components of the lighting circuit 200 are mounted on the substrate 710 .

A plurality of light emitting elements 706 correspond to the light emitting elements 112 in FIG. 2 and the like, and four light emitting elements 706 are connected in series to form the light source 110 . An example of the LED socket 700 is a combined stop lamp and tail lamp. In this case, a red LED chip is selected as the light emitting element 706, and when lighting as a stop lamp, a plurality of light emitting elements 706 light with a relatively large duty ratio (for example, 100%) and light as a tail lamp. In some cases, the plurality of light emitting elements 706 are lit with a relatively small duty ratio (eg, 5-10%).

Three pins 721 , 722 and 723 are exposed on the bottom side of the housing 702 . Pin 721 is supplied with the first input voltage _VIN1 through a switch, and pin 722 is supplied with the ground voltage. A pin 723 is supplied with a second input voltage _VIN2 which is high when the tail lamps are illuminated. The pins 721 to 723 penetrate the inside of the housing 702 and one end thereof is connected to the wiring pattern of the board 710 .

The second input voltage V _IN2 can correspond to the control signal S _CTRL in the second embodiment. Therefore, when the second input voltage _VIN2 is high, the lighting circuit 200 generates a pulse signal S _PWM having a relatively small duty ratio and blunts its waveform to generate a lamp current I _LAMP .

(Embodiment 3)
FIG. 10 is a block diagram of a lamp system 2G including the lamp 100G according to the third embodiment. The lighting fixture 100G includes two light sources 110_1 and 110_2 with different functions, and a lighting circuit 200G that controls lighting/lighting and brightness of the two light sources 110_1 and 110_2.

The first input terminal IN1 of the lamp 100G is supplied with the first input voltage _VIN1 that is active (high level) during the period in which the first light source 110_1 should be lit, and the second input terminal IN2 is supplied with the light source 110_2. A second input voltage _VIN2 is supplied which is active (high level) during the period to be switched. In this embodiment, it is assumed that the first input voltage _VIN1 and the second input voltage _VIN2 are not active at the same time. For example, the lighting system 2G includes switches 6a and 6b. When the switch 6a is on, the first input voltage _VIN1 is active, and when the switch 6b is on, the second input voltage _VIN2 is active.

The target brightness of the first light source 110_1 is lower than the target brightness of the second light source 110_2. Therefore, the number of light emitting elements 112 included in the first light source 110_1 (1 in this example) is less than the number of light emitting elements 112 included in the second light source 110_2 (3 in this example). In order to light the first light source 110_1 darker, the constant current circuit 220 performs PWM dimming (dimming) at the first duty ratio while the first light source 110_1 is lighting, and during lighting of the second light source 110_2, PWM dimming (dimming) is performed with a second duty ratio that is greater than the first duty ratio. In the following description, it is assumed that the second duty ratio is 100%.

The lighting circuit 200G includes a first series switch SWa1 and a second series switch SWa2 in addition to the constant current circuit 220, the dimming circuit 240, and the pulse generator 260 described above. The constant current circuit 220 can be composed of a linear regulator as described above, but is not limited to this, and may be composed of a DC/DC converter.

The first series switch SWa1 is provided in series with the first light source 110_1 on the first path. A second series switch SWa2 is provided in series with the second light source 110_2 on a second path parallel to the first path. The first series switch SWa1 is turned on during the lighting period of the first light source 110_1, and the second series switch SWa2 is turned on during the lighting period of the second light source 110_2. Therefore, the conduction/interruption (on/off) of the first series switch SWa1 and the second series switch SWa2 may be controlled based on the first input voltage V _IN1 and the second input voltage V _IN2 .

The pulse generator 260 generates a pulse signal S _PWM having a first duty ratio when the first input voltage V _IN1 is active and a second duty ratio when the first input voltage V _IN1 is inactive. to generate The pulse generator 260 receives the first input voltage V _IN1 as the control signal S _CTRL of FIG. 8, and selects the duty ratio of the pulse signal S _PWM based on the first input voltage V _IN1 .

The configuration and operation of the dimming circuit 240 and the constant current circuit 220 are as described above. The lighting circuit 200G is configured with the first input voltage _VIN1 and the second input voltage _VIN2 as the power supply voltage _VDD . For example, a diode OR circuit 270 may be provided, and the higher one of the first input voltage _VIN1 and the second input voltage _VIN2 may be used as the power supply voltage _VDD .

In the lighting period of the first light source 110_1, when the pulse signal S _PWM has a first duty ratio lower than 100%, the dimming signal V _ADIM becomes pulsed, and at least one of the positive edge and the negative edge is dulled. During the lighting period of the second light source 110_2, when the pulse signal S _PWM has a duty ratio of 100%, the dimming signal V _ADIM becomes a DC signal, so the drive current I _LED also becomes a DC signal.

The above is the configuration of the lamp 100G. Next, the operation will be explained. FIG. 11 is an operating waveform diagram of the lamp system 2G of FIG. Before period _t0 , both V _IN1 and V _IN2 are inactive, and both the first light source 110_1 and the second light source 110_2 are off.

At time _t0 , the first input voltage V _IN becomes active (battery voltage V _BAT ) as an instruction to turn on the first light source 110_1. be done. The first series switch SWa1 is turned on by the first input voltage _VIN1 . A pulse generator 260 generates a pulse signal S _PWM having a first duty ratio. The dimming circuit 240 dulls the positive edge and negative edge of the pulse signal S _PWM to generate the dimming signal V _ADIM . A constant current circuit 220 produces a drive current I _LED proportional to the dimming signal V _ADIM . As a result, the light source 110_1 is lit in a PWM dimmed state.

At time _t1 , as an instruction to turn on the second light source 110_2, the second input voltage V _IN2 becomes active (battery voltage V _BAT ) and the first input voltage V _IN becomes inactive (0 V). The second series switch SWa2 is turned on by the second input voltage _VIN2 . The pulse generator 260 produces a pulsed signal (actually non-pulsed) SP _PWM with a second duty ratio (100%). At this time, the dimming circuit 240 generates a DC dimming signal V _ADIM . A constant current circuit 220 produces a drive current I _LED proportional to the dimming signal V _ADIM . Thereby, the light source 110_2 is turned on. When the first input voltage _VIN2 becomes inactive at time _t2 , the second light source 110_2 turns off.

The above is the operation of the lamp 100G. According to this lamp 100G, the two light sources 110_1 and 110_2 can be caused to emit light with exclusively different luminances. Although PWM dimming is performed when the first light source 110_1 is lit, the generation of electromagnetic noise can be suppressed by dulling the waveform of the drive current _ILED , and countermeasures against electromagnetic noise can be simplified.

(Embodiment 4)
FIG. 12 is a block diagram of a lighting system 2H including a lighting fixture 100H according to the fourth embodiment. Similar to the third embodiment, this lamp 100H includes two light sources 110_1 and 110_2 with different functions, and a lighting circuit 200H that controls lighting/lighting and brightness of the two light sources 110_1 and 110_2.

In Embodiment 4, the first light source 110_1 is a lamp that lights steadily, and the second light source 110_2 is a lamp that repeats flickering in a human-perceivable cycle. In the following description, the first light source 110_1 is a clear lamp and includes a white light emitting element, and the light source 110_2 is a turn signal lamp and includes an amber light emitting element.

The first input voltage _VIN1 becomes active (high level) during the lighting period of the first light source 110_1. On the other hand, the second input voltage _VIN2 becomes active during the lighting period of the second light source 110_2, but is set to high at a predetermined period (0.7 seconds, duty ratio 50%) in order to blink the second light source 110_2. Alternate rows. A second input voltage V _IN2 may be generated by a relay 6c.

In the third embodiment, the first input voltage _VIN1 and the second input voltage _VIN2 are exclusively active. and When the two input voltages V _IN1 and V _IN2 are both active, the lighting circuit 200H prioritizes lighting of the second light source 110_2 and turns off the first light source 110_1.

A second input voltage _VIN2 is supplied to a second series switch SWa2. Therefore, the second series switch SWa2 is turned on and off according to the second input voltage _VIN2 while the second input voltage _VIN2 is active, thereby causing the second light source 110_2 to blink.

On the other hand, the first series switch SWa1 is controlled according to the first input voltage _VIN1 , but must be fixed off when the second input voltage _VIN2 is active. Therefore, the lamp 100G includes a switch controller 280. As shown in FIG. The switch controller 280 turns on the first series switch SWa1 when the second input voltage _VIN2 is inactive, and turns on the first series switch SWa1 when the second input voltage _VIN2 is active. Turn off.

The above is the configuration of the lamp system 2H. Next, the operation will be explained. FIG. 13 is an operating waveform diagram of the lamp system 2H of FIG. Before period _t0 , both V _IN1 and V _IN2 are inactive, and both the first light source 110_1 and the second light source 110_2 are off.

During the period t ₀ -t ₁ , only the first input voltage V _IN1 is active, turning on the first series switch SWa1. A pulse generator 260 generates a pulse signal S _PWM having a first duty ratio. The drive current I _LED generated by the constant current circuit 220 has a pulse shape with a first duty ratio and is supplied to the first light source 110_1.

During the period t ₁ -t ₂ , both the first input voltage V _IN1 and the second input voltage V _IN2 are active. At this time, the first series switch SWa1 is off and the second series switch SWa2 is on. A pulse generator 260 generates a pulse signal S _PWM having a second duty ratio (100%). The driving current _{I_LED} generated by the constant current circuit 220 is a direct current and supplied to the second light source 110_2.

Only the second input voltage V _IN2 is active during the period t ₂ -t ₃ . At this time, the first series switch SWa1 is off and the second series switch SWa2 is on. A pulse generator 260 generates a pulse signal S _PWM having a second duty ratio (100%). However, the power supply voltage V _DD is repeatedly supplied and interrupted in a time division manner according to the second input voltage V _IN2 . While the power supply voltage V _DD is interrupted, the constant current circuit 220, the dimming circuit 240 and the pulse generator 260 are inoperable, so the pulse signal S _PWM is low and the drive current I _LED is also 0A. In other words, it can be understood that the flickering of the second light source 110_2 is controlled during the period t ₂ to t ₃ by repeatedly interrupting and supplying the power supply voltage _VDD .

The above is the operation of the lamp system 2H. According to this lamp system 2H, it is possible to suppress electromagnetic noise when PWM dimming the first light source 110_1. Also, the second light source 110_2 can be blinked according to the second input voltage _VIN2 , and the first light source 110_1 can be turned off while the second light source 110_2 is blinking.

(Embodiment 5)
FIG. 14 is a block diagram of a lamp system 2I including the lamp 100I according to the fifth embodiment. The function of the lamp 100I in the fifth embodiment is the same as in the fourth embodiment.

The lighting circuit 200I includes a power selection circuit 290 instead of the diode OR circuit 270 in the fourth embodiment. Power supply selection circuit 290 outputs V _DD =V _IN1 when only the first input voltage V _IN1 is active, and intermittent power supply voltage V _DD =V _IN2 when the second input voltage V _IN2 is active. to output For example, power selection circuit 290 includes two diodes and an additional switch SWc. The switch SWc is turned off when the second input voltage _VIN2 is active, and turned on when the second input voltage _VIN2 is inactive. The on/off of the switch SWc may be interlocked with the first series switch SWa1.

The lighting circuit 200I includes a switch controller 280I instead of the switch controller 280 in the fourth embodiment. The switch controller 280I controls both the first series switch SWa1 and the second series switch SWa2. The control of the first series switch SWa1 is the same as in the fourth embodiment. When the second input voltage _VIN2 is inactive, the first series switch SWa1 is turned on and the second input voltage _VIN2 is active, the first series switch SWa1 is turned off.

The switch controller 280I fixedly turns on the second series switch SWa2 when the second input voltage _VIN2 is active, and turns on the second series switch SWa2 when the second input voltage _VIN2 is inactive. The switch SWa2 is turned off.

The above is the configuration of the lamp system 2I. Next, the operation will be explained. FIG. 15 is an operating waveform diagram of the lamp system 2I of FIG. Before period _t0 , both V _IN1 and V _IN2 are inactive, and both the first light source 110_1 and the second light source 110_2 are off.

Operations during periods t ₀ to t ₁ and periods t ₂ to t ₃ are the same as those in the fourth embodiment, and operations during periods t ₁ to t ₂ are different. Although both the first input voltage V _IN1 and the second input voltage V _IN2 are active during the period t ₁ to t ₂ , the second input voltage V _IN2 is intermittently supplied as the power supply voltage V _DD to the lighting circuit 200I. It differs from the fourth embodiment in that In FIG. 15, the operation during periods t ₁ to t ₂ is similar to that during periods t ₂ to t ₃ .

The above is the operation of the lamp system 2I. According to this lamp system 2I, it is possible to suppress electromagnetic noise when PWM dimming the first light source 110_1. Also, the second light source 110_2 can be blinked according to the second input voltage _VIN2 , and the first light source 110_1 can be turned off while the second light source 110_2 is blinking.

The present invention has been described above based on the embodiments. It should be understood by those skilled in the art that this embodiment is merely an example, and that various modifications can be made to the combination of each component and each treatment process, and that such modifications are within the scope of the present invention. be. Such modifications will be described below.

(Modification 1)
Although the constant current circuit 220 is configured as a source type in the embodiment, it may be configured as a sink type. FIG. 16 is a circuit diagram of a lamp 100E according to Modification 1. As shown in FIG. The lighting circuit 200E includes a sink type constant current circuit 220E. The anode of light source 110 is connected to power supply line 102 , and the output terminal of constant current circuit 220E is connected to the cathode of light source 110 . The constant current circuit 220E includes a sink type linear regulator 210E. V/I converter 230 and resistor R3 of FIG. 3 are omitted. This modification can also provide the same effect as the lamp 100 of FIG.

(Modification 2)
FIG. 17 is a circuit diagram of part of a lighting circuit 200F according to Modification 2. As shown in FIG. The linear regulator 210F includes a switch SW31 provided between the gate and source of the output transistor 212 (or between the gate and the power supply line 102).

In an ideal situation, from equation (2), the target amount I _REF of the lamp current I _LAMP is 0 A when V _ADIM '=V _DD . However, if the error amplifier 214 has an offset voltage, even if V _ADIM '=V _DD , the target amount I _REF may not become zero, and the light source 110 may turn on with low luminance. Therefore, by turning on the switch SW31 during the period in which the light source 110 should be extinguished, the output transistor 212 can be reliably turned off, and the lamp current _ILAMP can be made zero. A current limit resistor R _CL may be inserted at the output of the operational amplifier 214 . A current limit resistor _RCL can limit the current flowing through the switch SW31.

(Modification 3)
The LED socket 700 may be a dual-purpose lamp for both DRLs (Daytime Running Lamps) and clearance lamps. In this case, the plurality of light emitting elements 706 are white LED chips, and an appropriate duty ratio is selected according to the lighting mode.

(Modification 4)
In Embodiment 2 of FIG. 8, the control signal S _CTRL is once converted into a PWM signal, and the dimming signal V _ADIM is generated by dulling this PWM signal. The dimming signal V _ADIM may be generated directly from the control signal S _CTRL .

Although the present invention has been described using specific terms based on the embodiments, the embodiments merely show the principles and applications of the present invention, and the embodiments are defined in the scope of claims. Many modifications and changes in arrangement are permitted without departing from the spirit of the present invention.

2 lamp system 4 battery 6 switch 8 ECU
100 lamp 110 light source 112 light emitting element 200 lighting circuit 210 linear regulator 212 output transistor 214 error amplifier R1 resistor 220 constant current circuit 230 V/I converter 232 transistor 234 operational amplifier R2 resistor 240 dimming circuit C1 capacitor 242 charge/discharge circuit 260 pulse generation device 270 diode OR circuit 280 switch controller 290 power supply selection circuit 110_1 first light source 110_2 second light source SWa1 first series switch SWa2 second series switch

Claims (15)

A lighting circuit for a semiconductor light source,
a dimming circuit for generating a pulsed dimming signal having a duty ratio corresponding to the input pulse signal and having at least one edge dulled;
a constant current circuit that includes a linear regulator and stabilizes the lamp current flowing through the semiconductor light source to a target amount according to the dimming signal;
, wherein the lamp current has a waveform in which at least one edge is blunted according to the pulsed dimming signal . The dimming circuit is
a capacitor;
a charging and discharging circuit that charges and discharges the capacitor according to the pulse signal;
2. The lighting circuit of claim 1, wherein the dimming signal corresponds to the voltage of the capacitor. The charge/discharge circuit is
a first switch and a first resistor provided in series between one end of the capacitor and a reference voltage line;
a second switch provided between one end of the capacitor and a ground line;
3. The lighting circuit according to claim 2, wherein the first switch and the second switch complementarily switch according to the pulse signal. The charge/discharge circuit is
4. The lighting circuit of claim 3, further comprising a second resistor provided in series with the second switch between one end of the capacitor and the ground line. The charge/discharge circuit is
a first switch provided between one end of the capacitor and a reference voltage line;
a second switch and a second resistor provided in series between one end of the capacitor and a ground line;
3. The lighting circuit according to claim 2, wherein the first switch and the second switch complementarily switch according to the pulse signal. The charge/discharge circuit is
a first current source provided between one end of the capacitor and a reference voltage line;
a second current source provided between one end of the capacitor and a ground line;
3. The lighting circuit according to claim 2, wherein said first current source and said second current source are complementarily turned on in response to said pulse signal. The charge/discharge circuit is
a driver that outputs a high voltage and a low voltage according to the pulse signal;
a resistor provided between the output of the driver and one end of the capacitor;
3. The lighting circuit of claim 2, comprising: 8. The lighting circuit according to claim 1, further comprising a third switch provided between one of the power supply line and the ground line and the gate of the output transistor of the linear regulator. 9. The device according to any one of claims 1 to 8, further comprising a pulse generator that receives a control signal indicating luminance of said semiconductor light source and generates said pulse signal having a duty ratio corresponding to said control signal. lighting circuit. The semiconductor light source includes a first light source and a second light source that are commonly connected to one of an anode side and a cathode side,
The lighting circuit is
a first series switch in series with the first light source;
a second series switch in series with the second light source;
10. The lighting circuit of any one of claims 1 to 9, further comprising: a semiconductor light source;
a lighting circuit according to any one of claims 1 to 10;
A vehicle lamp comprising: a semiconductor light source;
a dimming circuit that receives a control signal that indicates the luminance of the semiconductor light source and generates a pulsed dimming signal that has a duty ratio according to the control signal and has at least one edge that is dull;
a constant current circuit that includes a linear regulator and stabilizes the lamp current flowing through the semiconductor light source to a target amount according to the dimming signal;
with
The vehicle lamp, wherein the lamp current has a waveform in which at least one edge is blunted according to the pulsed dimming signal . a first light source and a first series switch provided in series on the first path;
a second light source and a second series switch provided in series on a second path parallel to the first path;
a first input terminal for receiving a first input voltage that is active when the first light source is to be lit;
a second input terminal for receiving a second input voltage that becomes active when the second light source is to be lit;
a pulse generator for generating a pulse signal having a first duty ratio when the first input voltage is active and a second duty ratio when the first input voltage is inactive;
a dimming circuit for generating a pulsed dimming signal having a duty ratio corresponding to the pulse signal and having at least one edge dulled;
a constant current circuit that stabilizes the lamp current flowing through the light source including the first path and the second path to a target amount according to the dimming signal;
with
The vehicle lamp, wherein the lamp current has a waveform in which at least one edge is blunted according to the pulsed dimming signal . the second input voltage is a signal that alternates between high and low when active;
the second series switch is controlled to be on and off according to the second input voltage;
14. The vehicle lamp of claim 13, wherein the first series switch is turned on when the first input voltage is active and the second input voltage is inactive. the second input voltage is a signal that alternates between high and low when active;
15. The vehicle lamp according to claim 13, further comprising a switch controller that fixedly turns off the first series switch when the second input voltage is active.

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