Patent Application
20240042862
The present disclosure relates to a lamp to be employed in an automobile or the like.
An automotive lamp (e.g., headlamp) has multiple functions, such as a high beam, low beam, clearance lamp (position lamp), Daytime Running Lamp (DRL), etc.
When the input voltage VIN is supplied, the constant current driver 310 outputs a driving current ILED. When the switching terminal SEL is set to the low level, the switching circuit 320 turns on the switch SW1 and turns off the switch SW2. In this state, the driving current ILED flows through the LEDs 301 and 302. Conversely, when the switching terminal SEL is set to the high level, the switching circuit 320 turns off the switch SW1 and turns on the switch SW2. In this state, the driving current ILED flows through the LEDs 301 and 303.
For example, the LED 301 shown in
In the automotive lamp 100 shown in
The present disclosure has been made in view of such a situation.
1. An automotive lamp according to an embodiment of the present disclosure includes: a first semiconductor light source coupled between a first node and a second node; a second semiconductor light source coupled between the second node and a third node so as to form a first path; a third semiconductor light source coupled between the second node and the third node so as to form a second path parallel to the first path; and a lighting circuit structured to drive the first semiconductor light source, the second semiconductor light source, and the third semiconductor light source. The lighting circuit is structured to be switchable between a first lighting mode in which the first semiconductor light source and the second semiconductor light source are turned on and the third semiconductor light source is turned off, and a second lighting mode in which the first semiconductor light source and the third semiconductor light source are turned on and the second semiconductor light source is turned on so as to be dimmer than in the first lighting mode.
2. An automotive lamp according to an embodiment of the present disclosure includes: a first semiconductor light source coupled between a first node and a second node; a second semiconductor light source coupled between the second node and a third node so as to form a first path; a third semiconductor light source coupled between the second node and the third node so as to form a second path that is parallel to the first path; a lighting circuit structured to receive a power supply voltage, structured to turn on the first semiconductor light source and the second semiconductor light source in a first lighting mode, and to turn on the first semiconductor light source and the third semiconductor light source in a second lighting mode; and a bypass circuit arranged between the second node and the third node, and structured to turn on when the power supply voltage becomes lower than a predetermined first threshold value.
It should be noted that any combination of the components described above, any component described above, or any manifestation described above may be mutually substituted between a method, apparatus, system, and so forth, which are also effective as an embodiment of the present invention.
Embodiments will now be described, by way of example only, with reference to the accompanying drawings which are meant to be exemplary, not limiting, and wherein like elements are numbered alike in several Figures, in which:
Description will be made regarding the outline of several exemplary embodiments of the present disclosure. The outline is a simplified explanation regarding several concepts of one or multiple embodiments as a preface to the detailed description described later in order to provide a basic understanding of the embodiments. That is to say, the outline described below is by no means intended to restrict the scope of the present invention and the present disclosure. Furthermore, the outline described below is by no means a comprehensive outline of all possible embodiments. That is to say, the outline is by no means intended to identify the indispensable or essential elements of all the embodiments, and is by no means intended to define the scope of a part of or all the embodiments. For convenience, in some cases, an “embodiment” as used in the present specification represents a single or multiple embodiments (examples and modifications) disclosed in the present specification.
An automotive lamp according to one embodiment includes: a first semiconductor light source coupled between a first node and a second node; a second semiconductor light source coupled between the second node and a third node so as to form a first path; a third semiconductor light source coupled between the second node and the third node so as to form a second path parallel to the first path; and a lighting circuit structured to drive the first semiconductor light source, the second semiconductor light source, and the third semiconductor light source. The lighting circuit is structured to be switchable between a first lighting mode in which the first semiconductor light source and the second semiconductor light source are turned on and the third semiconductor light source is turned off, and a second lighting mode in which the first semiconductor light source and the third semiconductor light source are turned on and the second semiconductor light source is turned on so as to be dimmer than in the first lighting mode.
With this arrangement, when the lighting mode is switched from the first lighting mode to the second lighting mode, the third semiconductor light source is additionally turned on while the second semiconductor light source remains turned on. Accordingly, this provides an improved appearance when the automotive lamp is viewed from the surroundings as compared with an arrangement in which the third semiconductor light source is turned on in exchange for turning off the second semiconductor light source.
In one embodiment, the automotive lamp may further include: an input terminal structured to receive a power supply voltage that also has a function as a turn-on instruction; and a switching terminal structured to be controlled by an external circuit such that it is set to a first state in the first lighting mode and to a second state in the second lighting mode. Also, the lighting circuit may include: a first constant current driver having an output node coupled to the first node, and structured to output a first driving current when the power supply voltage is supplied to the input terminal; a first switch coupled between the second node and the second semiconductor light source on the first path; a second switch coupled in series with the third semiconductor light source on the second path; a switching circuit structured to turn on the first switch and turn off the second switch when the switching terminal is set to the first state, and to turn off the first switch and turn on the second switch when the switching terminal is set to the second state; and a second constant current driver structured to supply a second driving current that is smaller than the first driving current to an intermediate node that couples the second semiconductor light source and the first switch when the switching terminal is set to the second state.
When the switching terminal is set to the first state, the lighting mode is set to the first lighting mode. In this state, the first switch is turned on, and the first driving current is supplied to each of the first semiconductor light source and the second semiconductor light source. Accordingly, the first semiconductor light source and the second semiconductor light source are turned on. When the switching terminal is set to the second state, the lighting mode is set to the second lighting mode. In this state, the first switch is turned off, and accordingly, the first driving current does not flow through the second semiconductor light source. Instead, the second constant current driver supplies the second driving current. As a result, in the second lighting mode, such an arrangement is capable of emitting light the second semiconductor light source more dimly than in the first lighting mode.
In one embodiment, the second constant current driver may include a current-limiting resistor arranged between the switching terminal and the intermediate node.
In one embodiment, the second constant current driver may further include a diode arranged in series with the current-limiting resistor between the switching terminal and the intermediate node.
In one embodiment, the second driving current may flow via the switching terminal. In one embodiment, the second driving current may be larger than 10 mA. In this case, this is capable of flowing the second driving current as a contact current through the switching terminal during the second lighting mode. That is to say, the driving current for the second semiconductor light source can also be used as a contact current for preventing oxidation, thereby allowing an increase in unnecessary power consumption to be suppressed.
In one embodiment, in the second state, a non-zero switching voltage may be input to the switching terminal. Also, in the second state, power may be supplied to the second constant current driver via the switching terminal. With this, in the first state, when the switching terminal is set to the high-impedance state or the low-level state (zero voltage), the second constant current driver becomes inactive.
In one embodiment, the automotive lamp may further include: an input terminal structured to receive a power supply voltage that also functions as a turn-on instruction; and a switching terminal structured to be controlled by an external circuit such that it is set to a first state in the first lighting mode and to a second state in the second lighting mode. Also, the lighting circuit may include: a first constant current driver having an output node coupled to the first node, and structured to output a first driving current when the power supply voltage is supplied to the input terminal; a second constant current driver coupled between the second semiconductor light source and the third node on the first path, and structured to be switchable between a constant current state in which a second driving current that is smaller than the first driving current is generated and a full-on state; a second switch coupled in series with the third semiconductor light source on the second path; and a switching circuit structured to set the second constant current driver to the full-on state and turn off the second switch when the switching terminal is set to the first state, and to set the second constant current driver to the constant current state and to turn on the second switch when the switching terminal is set to the second state.
When the switching terminal is set to the first state, the second constant current driver is set to a full-on state. In this state, the first driving current is supplied to the first semiconductor light source and the second semiconductor light source, thereby turning on the first semiconductor light source and the second semiconductor light source (first lighting mode). When the switching terminal is set to the second state, the second driving current generated by the second constant current driver flows through the second semiconductor light source. In this state, the second semiconductor light source emits light dimly. In contrast, the first driving current flows through the first semiconductor light source and the third semiconductor light source. Accordingly, the first semiconductor light source and the third semiconductor light source each emit light brightly (second lighting mode).
In one embodiment, the second constant current driver may include: a first transistor and a first resistor coupled in series between the second semiconductor light source and the third node on the first path; and a feedback circuit structured to be activated when the switching terminal is set to the second state, so as to control a voltage applied to a control terminal of the first transistor such that voltage drop across the first resistor approaches a target voltage. When the switching terminal is set to the second state, the second driving current represented by I=VREF/R1 flows through the first transistor. Here, V REF represents the reference voltage, and R1 represents the resistance value of the first resistor. As a result, in the second lighting mode, this allows the second semiconductor light source to emit light more dimly than in the first lighting mode.
In the present specification, the phrase “circuit A outputs current” include both a case in which the circuit A functions as a source of a current, and a case in which current is sunk to the circuit A.
In one embodiment, the automotive lamp may further include: an input terminal structured to receive a power supply voltage that also functions as a turn-on instruction; and a switching terminal structured to be controlled by an external circuit such that it is set to a first state in the first lighting mode and to a second state in the second lighting mode. Also, the lighting circuit may include: a first constant current driver having an output node coupled to the first node, and structured to output a first driving current when the power supply voltage is supplied to the input terminal; a first switch coupled in series with the second semiconductor light source on the first path; a second switch coupled in series with the third semiconductor light source on the second path; and a switch control circuit structured to turn on the first switch and turn off the second switch when the switching terminal is set to the first state, and to switch on and off the first switch according to a pulse signal having a first duty cycle that is lower than 50% and to switch on and off the second switch according to a signal complementary to the pulse signal when the switching terminal is set to the second state.
When the switching terminal is set to the first state, the lighting mode is set to the first lighting mode. In this state, the first switch is turned on, and the first driving current is supplied to the first semiconductor light source and the second semiconductor light source. Accordingly, the first semiconductor light source and the second semiconductor light source are turned on. When the switching terminal is set to the second state, the lighting mode is set to the second lighting mode. In this state, the first switch and the second switch are switched on and off with complementary duty cycles d1 and d2 (d1<d2). The first driving current is divided into currents with a ratio of d1:d2, which are applied to the second semiconductor light source and the third semiconductor light source, respectively. Accordingly, this allows the second semiconductor light source to emit light more dimly than in the first lighting mode.
In one embodiment, in the second lighting mode, the first constant current driver may increase the first driving current as compared with the first lighting mode.
In one embodiment, when the lighting mode is switched between the first lighting mode and the second lighting mode, a period in which the first switch and the second switch are turned on at the same time may be inserted. This is capable of preventing the field of view from becoming dim due to the first switch and the second switch both turning off at the same time, i.e., due to all the semiconductor light sources turning off. Furthermore, this suppresses the overvoltage state and overcurrent.
In one embodiment, the output light of the first semiconductor light source may form a light distribution pattern having an upper edge that defines a horizontal cutoff line. Also, the output light of the second semiconductor light source may form a light distribution pattern having an upper edge that defines an oblique cutoff line. Also, the output light of the third semiconductor light source may form a light distribution pattern to be used for a high beam.
An automotive lamp according to one embodiment includes: a first semiconductor light source coupled between a first node and a second node; a second semiconductor light source coupled between the second node and a third node so as to form a first path; a third semiconductor light source coupled between the second node and the third node so as to form a second path that is parallel to the first path; a lighting circuit structured to receive a power supply voltage, structured to turn on the first semiconductor light source and the second semiconductor light source in a first lighting mode, and to turn on the first semiconductor light source and the third semiconductor light source in a second lighting mode; and a bypass circuit arranged between the second node and the third node, and structured to turn on when the power supply voltage becomes lower than a predetermined first threshold value.
With this arrangement in which the bypass switch is turned on in the low-voltage state, this is capable of maintaining the light emission of the first semiconductor light source regardless of the lighting mode. This allows a minimum field view to be illuminated.
In one embodiment, the bypass switch may turn off when the power supply voltage exceeds a second threshold value that is higher than the first threshold value. With such an arrangement in which the threshold voltage is provided with hysteresis, this is capable of preventing blinking in the second semiconductor light source or the third semiconductor light source due to the bypass switch repeatedly switching on and off.
In one embodiment, the output light of the first semiconductor light source may form a light distribution pattern having an upper edge that defines a horizontal cutoff line. Also, the output light of the second semiconductor light source may form a light distribution pattern having an upper edge that defines an oblique cutoff line. Also, the output light of the third semiconductor light source may form a light distribution pattern to be used for a high beam. This is capable of maintaining illumination of a region below the horizontal cutoff line even in the low-voltage state.
In one embodiment, in the second lighting mode, the lighting circuit may turn on the second semiconductor light source so as to be dimmer than in the first lighting mode.
With this arrangement, when the lighting mode is switched from the first lighting mode to the second lighting mode, the third semiconductor light source is additionally turned on while the second semiconductor light source remains turned on. This provides an improved appearance when the automotive lamp is viewed from the surroundings as compared with an arrangement in which the third semiconductor light source is turned on in exchange for turning off the second semiconductor light source.
In one embodiment, the automotive lamp may further include: an input terminal structured to receive a power supply voltage that also functions as a turn-on instruction; and a switching terminal structured to be controlled from an external circuit such that it is set to a first state in the first lighting mode and set to a second state in the second lighting mode. Also, the lighting circuit may include: a first constant current driver having an output node coupled to the first node, and structured to output a first driving current when the power supply voltage is supplied to the input terminal; a first switch coupled between the second node and the second semiconductor light source on the first path; a second switch coupled in series with the third semiconductor light source on the second path; a switching circuit structured to turn on the first switch and turn off the second switch when the switching terminal is set to the first state, and to turn off the first switch and turn on the second switch when the switching terminal is set to the second state; and a second constant current driver structured to supply a second driving current that is smaller than the first driving current to an intermediate node that couples the second semiconductor light source and the first switch when the switching terminal is set to the second state.
When the switching terminal is set to the first state, the lighting mode is set to the first lighting mode. In this state, the first switch is turned on, and the first driving current is supplied to each of the first semiconductor light source and the second semiconductor light source. Accordingly, the first semiconductor light source and the second semiconductor light source are turned on. When the switching terminal is set to the second state, the lighting mode is set to the second lighting mode. In this state, the first switch is turned off, and accordingly, the first driving current does not flow through the second semiconductor light source. Instead, the second constant current driver supplies the second driving current. As a result, in the second lighting mode, such an arrangement is capable of emitting light the second semiconductor light source more dimly than in the first lighting mode.
In one embodiment, the automotive lamp may further include: an input terminal structured to receive a power supply voltage that also functions as a turn-on instruction; and a switching terminal structured to be controlled by an external circuit such that it is set to a first state in the first lighting mode and to a second state in the second lighting mode. Also, the lighting circuit may further include: a first constant current driver having an output node coupled to the first node, and structured to output a first driving current when the power supply voltage is supplied to the input terminal; a second constant current driver coupled between the second semiconductor light source and the third node on the first path, and structured to be switchable between a constant current state in which a second driving current that is smaller than the first driving current is generated and a full-on state; a second switch coupled in series with the third semiconductor light source on the second path; and a switching circuit structured to set the second constant current driver to the full-on state and turn off the second switch when the switching terminal is set to the first state, and to set the second constant current driver to the constant current state and to turn on the second switch when the switching terminal is set to the second state.
When the switching terminal is set to the first state, the second constant current driver is set to a full-on state. In this state, the first driving current is supplied to the first semiconductor light source and the second semiconductor light source, thereby turning on the first semiconductor light source and the second semiconductor light source (first lighting mode). When the switching terminal is set to the second state, the second driving current generated by the second constant current driver flows through the second semiconductor light source. In this state, the second semiconductor light source emits light dimly. In contrast, the first driving current flows through the first semiconductor light source and the third semiconductor light source. Accordingly, the first semiconductor light source and the third semiconductor light source each emit light brightly (second lighting mode).
In one embodiment, the automotive lamp may further include: an input terminal structured to receive a power supply voltage that also functions as a turn-on instruction; and a switching terminal structured to be controlled by an external circuit such that it is set to a first state in the first lighting mode and to a second state in the second lighting mode. Also, the lighting circuit may include: a first constant current driver having an output node coupled to the first node, and structured to output a first driving current when the power supply voltage is supplied to the input terminal; a first switch coupled in series with the second semiconductor light source on the first path; a second switch coupled in series with the third semiconductor light source on the second path; and a switch control circuit structured to turn on the first switch and turn off the second switch when the switching terminal is set to the first state, and to switch on and off the first switch according to a pulse signal having a first duty cycle that is lower than 50% and to switch on and off the second switch according to a signal complementary to the pulse signal when the switching terminal is set to the second state.
When the switching terminal is set to the first state, the lighting mode is set to the first lighting mode. In this state, the first switch is turned on, and the first driving current is supplied to the first semiconductor light source and the second semiconductor light source. Accordingly, the first semiconductor light source and the second semiconductor light source are turned on. When the switching terminal is set to the second state, the lighting mode is set to the second lighting mode. In this state, the first switch and the second switch are switched on and off with complementary duty cycles d1 and d2 (d1<d2). The first driving current is divided into currents with a ratio of d1:d2, which are applied to the second semiconductor light source and the third semiconductor light source, respectively. Accordingly, this allows the second semiconductor light source to emit light more dimly than in the first lighting mode.
Description will be made below regarding preferred embodiments with reference to the drawings. In each drawing, the same or similar components, members, and processes are denoted by the same reference numerals, and redundant description thereof will be omitted as appropriate. The embodiments have been described for exemplary purposes only, and are by no means intended to restrict the present disclosure and the present invention. Also, it is not necessarily essential for the present invention that all the features or a combination thereof be provided as described in the embodiments.
In the present specification, a state represented by the phrase “the member A is coupled to the member B” includes a state in which the member A is indirectly coupled to the member B via another member that does not substantially affect the electrical connection between them, or that does not damage the functions or effects of the connection between them, in addition to a state in which they are physically and directly coupled.
Similarly, a state represented by the phrase “the member C is provided between the member A and the member B” includes a state in which the member A is indirectly coupled to the member C, or the member B is indirectly coupled to the member C via another member that does not substantially affect the electrical connection between them, or that does not damage the functions or effects of the connection between them, in addition to a state in which they are directly coupled.
In the present specification, the reference symbols denoting electric signals such as a voltage signal, current signal, or the like, and the reference symbols denoting circuit elements such as a resistor, capacitor, or the like, also represent the corresponding voltage value, current value, resistance value, or capacitance value as necessary.
The automotive lamp 100 includes a main input terminal VIN, a switching terminal SEL, and a ground terminal GND. The ground GND is grounded. The input terminal VIN receives the supply of a voltage V BAT from a battery 2 via a switch 4 arranged on the vehicle side. On the vehicle side, upon turning on a lighting switch for a headlamp by the driver, the switch 4 is turned on, which supplies a power supply voltage VIN to the input terminal VIN. The power supply voltage VIN has two functions, i.e., a function as a power supply voltage for the automotive lamp 100 and a function as a lighting instruction.
Furthermore, the electrical state of the switching terminal SEL of the automotive lamp 100 is switched between the first state and the second state according to the lighting mode of the automotive lamp 100. In the present embodiment, the first state is a no-input (high-impedance) state. The second state is a state in which a non-zero voltage is input. Specifically, the switching terminal SEL is coupled to the battery 2 via a switch 6 arranged on the vehicle side. On the vehicle side, when the driver selects the low-beam mode (first lighting mode), the switch 6 is turned off so as to set the switching terminal SEL to a no-input (high-impedance) state.
When the driver selects the high-beam mode (second lighting mode), the switch 6 is turned on so as to supply a switching voltage VSEL having a high level (battery voltage) to the switching terminal SEL.
The automotive lamp 100 is configured as a lamp module that is switchable between the high-beam mode and the low-beam mode. The automotive lamp 100 includes a first semiconductor light source 101, a second semiconductor light source 102, a third semiconductor light source 103, and a lighting circuit 200. The first semiconductor light source 101, the second semiconductor light source 102, and the third semiconductor light source 103 are each configured as a white light-emitting diode (LED), for example.
The first semiconductor light source 101 through the third semiconductor light source 103 are coupled such that the current that flows through the first semiconductor light source 101 is the sum total of the currents that flow through the second semiconductor light source 102 and the third semiconductor light source 103. Specifically, the first semiconductor light source 101 is coupled between a first node n1 and a second node n2. The second semiconductor light source 102 is coupled between the second node n2 and a third node n3 so as to form a first path. The third semiconductor light source 103 is coupled between the second node n2 and the third node n3 so as to form a second path that is parallel to the first path.
The lighting circuit 200 drives the first semiconductor light source 101 through the third semiconductor light source 103. In the first lighting mode (low-beam mode), the lighting circuit 200 turns on the first semiconductor light source 101 and the second semiconductor light source 102, and turns off the third semiconductor light source 103. In the second lighting mode, the lighting circuit 200 turns on the first semiconductor light source 101 and the third semiconductor light source 103, and turns on the second semiconductor light source 102 so as to be dimmer than the first lighting mode. The first semiconductor light source 101 is preferably operated to provide almost no change in brightness between the first lighting mode and the second lighting mode.
The lighting circuit 200 includes a first constant current driver 210, a switching circuit 220, a second constant current driver 230, a first switch SW1, and a second switch SW2.
The first constant current driver 210 has its output node OUT coupled to the anode (first node n1) of the first semiconductor light source 101. When the power supply voltage VIN is supplied to the input terminal VIN, the first constant current driver 210 is activated, and outputs a first driving current IOUT1. The first constant current driver 210 may be configured as a switching converter that outputs a constant current. Also, the first constant current driver 210 may be configured as a constant current output linear regulator or other kinds of constant current circuits.
In the present embodiment, the third node n3, i.e., the cathode of the second semiconductor light source 102 and the cathode of the third semiconductor light source 103 are grounded. The first switch SW1 is arranged between the cathode (second node n2) of the first semiconductor light source 101 and the anode of the second semiconductor light source 102. The second switch SW2 is arranged between the cathode (second node n2) of the first semiconductor light source 101 and the anode of the third semiconductor light source 103.
In the first state (high impedance, no input) of the switching terminal SEL, the switching circuit 220 turns on the first switch SW1 and turns off the second switch SW2. On the other hand, in the second state of the switching terminal SEL, i.e., when the switching voltage VSEL is supplied, the switching circuit 220 turns off the first switch SW1 and turns on the second switch SW2.
The second constant current driver 230 is coupled to the switching terminal SEL. When the switching voltage VSEL is supplied to the switching terminal SEL, the second constant current driver 230 becomes active, and supplies a second driving current IOUT2 that is smaller than the first driving current IOUT1 to the anode of the second semiconductor light source 102. The second driving current IOUT2 may preferably be determined to the extent that, in the second state, a region including the second semiconductor light source 102 can be visible as being turned on when viewed from the exterior of the automotive lamp 100. For example, the second driving current IOUT2 may preferably be determined to be larger than 10 mA.
The above is the configuration of the automotive lamp 100. Next, description will be made regarding the operation thereof.
The above is the operation of the automotive lamp 100.
With the automotive lamp 100, when the lighting mode is switched from the first lighting mode (low-beam mode) to the second lighting mode (high-beam mode), the third semiconductor light source 103 is additionally turned on in a state in which the second semiconductor light source 102 remains turned on. Accordingly, this is capable of preventing a portion that had been bright from suddenly becoming dim immediately after the mode switching as viewed from the surroundings of the automotive lamp 100, thereby providing an improved appearance.
Furthermore, with the automotive lamp 100, even in the second lighting mode, the second semiconductor light source remains turned on. Accordingly, this is capable of preventing the brightness of a region illuminated by the second semiconductor light source 102 on a virtual vertical screen from changing significantly.
For example, let us consider an arrangement in which the optical system of the automotive lamp 100 is designed such that the output light of the first semiconductor light source 101, the second semiconductor light source 102, and the third semiconductor light source 103 are respectively emitted to the regions A1, A2, and A3 shown in
In this case, in a case in which the second semiconductor light source 102 is designed to be turned off in the second lighting mode, the region A2 becomes dim. In particular, in this state, the region L2 is not illuminated by any one of the light sources. In contrast, with the present embodiment, the second semiconductor light source 102 remains turned on in the second lighting mode. Accordingly, in this state, light is emitted to the region A2, thereby suppressing an unnatural change in the light distribution.
Furthermore, in the second lighting mode, the driving current IOUT2 that flows through the second semiconductor light source 102 is smaller than the driving current ‘purr’ that flows through in the first lighting mode. Accordingly, this involves only a slight increase in the heat generation (power consumption) due to the second semiconductor light source 102 remaining turned on. Accordingly, there is no need to apply an additional heat-generation countermeasure. Alternatively, such an arrangement requires only a minor countermeasure. This is capable of suppressing an increase in cost.
Furthermore, by designing the amount of the second driving current IOUT2 to be larger than 10 mA, this allows a contact current exceeding 10 mA required to prevent oxidation of the connector terminal to flow through the switching terminal SEL. That is to say, the driving current IOUT2 of the second semiconductor light source 102 also has a function for preventing oxidation, thereby suppressing an increase in unnecessary power consumption.
I
OUT2=(VSEL−Vf2−Vf3)/R3=(VBAT−Vf2−Vf3)/R3
That is to say, the amount of the second driving current IOUT2 can be determined according to the resistance value of the current-limiting resistor R3. Furthermore, with such an arrangement provided with the diode D3, this is capable of preventing the first driving current IOUT1 generated by the first constant current driver 210 from flowing into the switching terminal SEL or the switching circuit 220. It should be noted that, in a case in which the switching circuit 220 has a sufficiently high input impedance, the diode D3 may be omitted.
The first switch SW1 includes a first transistor M1 configured as an N-channel MOSFET and resistors R11 and R12. Similarly, the second switch SW2 includes a second transistor M2 configured as a MOSFET and resistors R21 and R22. The first switch SW1 and the second switch SW2 are each configured such that, upon inputting the high level to the gate, the corresponding switch is turned on, and upon inputting the low level to the gate, the corresponding switch is turned off. It should be noted that the configurations of the switches SW1 and SW2 are not restricted to such arrangements.
When the switching terminal SEL is set to the first state (no input, low level, high impedance), the switching circuit 220 sets the control terminal of the first switch SW1 to the high-level state, and sets the control terminal of the second switch SW2 to the low-level state. Conversely, when the switching terminal SEL is set to the second state (high level (VSEL=VBAT)), the switching circuit 220 sets the control terminal of the first switch SW1 to the low-level state, and sets the control terminal of the second switch SW2 to the high-level state.
That is to say, the switching circuit 220 supplies a first output signal S1 having a logical value complementary to that of the signal input to the switching terminal SEL to the first switch SW1, and supplies a second output signal S2 having the same logical value as that of the signal input to the switching terminal SEL to the second switch SW2.
The switching circuit 220 includes transistors Q11 through Q14 and a resistor R4. When the switching terminal SEL is set to the low-level state or the high-impedance state, the transistors Q11 and Q12 are turned off and the transistor Q14 is turned on. Accordingly, the high-level signal S1 is input to the control terminal of the first switch SW1. In this state, the transistor Q13 is turned off. Accordingly, the control terminal of the second switch SW2 is set to the low level.
Conversely, when the switching terminal SEL is set to the high-level state, the transistors Q11 and Q12 are turned on, and the transistor Q14 is turned off. Accordingly, the control terminal of the first switch SW1 is set to the low-level state. In this state, the transistor Q13 is turned on. Accordingly, the control terminal of the second switch SW2 is set to the high-level state.
It can be understood by those skilled in this art that the configurations of the first switch SW1, the second switch SW2, the switching circuit 220, and the second constant current driver 230 are not restricted to those shown in
In
In this modification, the first switch SW1 further includes a capacitor C1. One end of the capacitor C1 is coupled to the drain (or collector) of the transistor M1. The other end of the capacitor C1 is coupled to the control terminal (i.e., gate or base) of the switching transistor M1.
Description will be made regarding the turn-on operation of the switch SW1. When the gate voltage VG increases to the vicinity of the gate-source threshold voltage VGS(th) of the transistor M1, the rate of increase of the gate voltage VG becomes very slow due to the Miller effect caused by the capacitor C1. This allows the switch SW1 to be gradually turned on.
The same can be said of the turn-off operation. When the gate voltage VG decreases to the vicinity of the gate-source threshold voltage VGS(th) of the transistor M1, the rate of decrease of the gate voltage VG becomes very slow due to the Miller effect caused by the capacitor C1. This allows the switch SW1 to be gradually turned off.
With such an arrangement in which the capacitor C1 is additionally provided to the first switch SW1 (and the second switch SW2), this is capable of gradually turning on and off the switch. This allows the light intensities of the second semiconductor light source 102 and the third semiconductor light source 103 to be gradually changed. That is to say, this supports gradual turn-on and gradual turn-off. Furthermore, this is capable of preventing a sudden change in the electric potential at the anode or the cathode of each of the first semiconductor light source 101 through the third semiconductor light source 103.
Furthermore, in
If there is an off section in which both the first switch SW1 and the second switch SW2 are turned off, the first constant current driver 210 enters a no-load state. This leads to an increase in the output voltage VOUT, resulting in an overvoltage state. When the first switch SW1 or the second switch SW2 is turned on in a state in which the output voltage VOUT increases, overcurrent flows through the LED. In contrast, with such an arrangement shown in
When the high-side transistor MP of the output stage of the switching circuit 220 is turned on, the gate of the transistor M1 is charged via a parallel connection circuit formed of the resistors R11 and R13, thereby raising the gate voltage VG. When the low-side transistor MN of the output stage of the switching circuit 220 is turned on, the gate of the transistor M1 is discharged via the resistor R11, thereby reducing the gate voltage VG.
With this, there is a difference in impedance between the charging path and the discharging path.
Accordingly, the gate voltage VG increases at a rate that is higher than a rate at which the gate voltage V G decreases. This allows the first switch SW1 to be turned on in a short period of time and to be turned off slowly. That is to say, this allows the light intensity of the second semiconductor light source 102 to be gradually reduced (gradual turn-off). The same can be said of the third semiconductor light source 103.
With the configuration shown in
The first switch SW1 shown in
When the high-side transistor MP of the output stage of the switching circuit 220 is turned on, the gate of the transistor M1 is charged via a parallel connection circuit formed of the resistors R11 and R13, thereby raising the gate voltage VG. When the low-side transistor MN of the output stage of the switching circuit 220 is turned on, the gate of the transistor M1 is discharged via the resistor R11, thereby lowering the gate voltage VG.
When the control signal S1 is set to the low level, the transistor M11 is turned on, and accordingly, the gate of the transistor M1 is charged via the resistor R11. In this state, the gate voltage VG increases, thereby turning on the transistor M1. Conversely, when the control signal S1 is set to the high level, the transistor M12 is turned on, and accordingly, the gate of the transistor M1 is discharged via the resistors R11 and R14. In this state, the gate voltage VG decreases, thereby turning off the transistor M1.
With this, there is a difference in impedance between the charging path and the discharging path. Accordingly, the gate voltage VG increases at a rate that is higher than a rate at which the gate voltage V G decreases. As with the arrangements shown in
With the configuration shown in
Furthermore, with the configuration shown in
Components of the lighting circuit 200 and a connector 144 are mounted on a printed circuit board 142. The connector 144 includes three terminals, i.e., an input terminal VIN, a switching terminal SEL, and a ground terminal GND. The wiring of the printed circuit board 142 is coupled to the electrodes of the first semiconductor light source 101 through the third semiconductor light source 103 via bonding wires. It should be noted that the printed circuit board 142 may be omitted. In this case, the components of the lighting circuit 200 and the connector 144 may be directly mounted on the radiator plate 146. Furthermore, in the present embodiment, the heat generation of the automotive lamp 100 is reduced. Accordingly, the radiator plate 146 having a thin thickness may be employed. However, instead of such a thin radiator plate 146, a heat sink having a large thickness may be employed. The connector 144 is not restricted to such a connector to be mounted. Also, other types of connectors such as a card edge connector or the like may be employed.
A lens module 150 includes a first lens 151, a second lens 152, and a third lens 153. The first lens 151 receives the output beam of the first semiconductor light source 101, and projects the output beam to a low-beam diffusion region A1. The second lens 152 receives the output beam of the second semiconductor light source 102, and projects it to a low-beam focusing region A2. The third lens 153 receives the output beam of the third semiconductor light source 103, and projects it to a high-beam region A3.
Next, description will be made regarding modifications relating to the embodiment 1.
With this modification, the same effects can be obtained as those of the automotive lamp 100 shown in
With the automotive lamp 100B, in the second lighting mode, this is capable of preventing the illumination region of the semiconductor light source 102 from becoming significantly dimmer in the second lighting mode.
It should be noted that, in the automotive lamp 100B, the switching terminal SEL has a high impedance. Accordingly, during the second lighting mode, almost no contact current flows. Accordingly, in order to prevent oxidation of the connector terminal, there is a need to additionally provide an arrangement configured to flow contact current. In other words, with an arrangement configured to supply the power supply voltage of the second constant current driver 230 from the switching terminal SEL, i.e., with an arrangement in which the second driving current IOUT2 is supplied from the switching terminal SEL, the operating current of the second constant current driver 230 continuously flows during the second lighting mode.
Such arrangement requires no additional configuration for preventing oxidation of the connector terminal.
The positions of the second switch SW2 and the third semiconductor light source 103 may be interchanged.
Each bipolar transistor may be replaced by a Metal Oxide Semiconductor Field Effect Transistor (MOSFET). In this case, the base, collector, and emitter correspond to the gate, drain, and source, respectively. Also, each NPN (N-channel) transistor may be replaced by a PNP (P-channel) transistor.
With this modification, in the second lighting mode, the current IOUT2 generated by the second constant current driver 230A flows through the first semiconductor light source 101 in addition to the second semiconductor light source 102. This is the point of difference from the arrangement shown in
With this modification, in the second lighting mode, the current IOUT2 generated by the second constant current driver 230A flows through the first semiconductor light source 101 in addition to the second semiconductor light source 102. This is the point of difference from the arrangement shown in
A second constant current driver 230H is coupled in parallel with the first switch SW1. In the first lighting mode, the switching circuit 220 turns on the first switch SW1 and turns off the second switch SW2. In the second lighting mode, the switching circuit 220 turns off the first switch SW1 and turns on the second switch SW2.
When the switching terminal SEL is set to the first state, the second constant current driver 230H is disabled. On the other hand, when the switching terminal SEL is set to the second state, the second constant current driver 230H is enabled. In this state, the second constant current driver 230H generates the second driving current IOUT2.
The second constant current driver 230E is coupled between the third node n3 and the second semiconductor light source 102 on the first path. The second constant current driver 230E is configured to be switchable between a full-on state and a constant current state in which the second driving current IOUT2 that is smaller than the first driving current IOUT1 is generated. The full-on state is a state in which the impedance is set to a very small value, which corresponds to the on state of the first switch SW1.
When the switching terminal SEL is set to the first state, the switching circuit 220 sets the second constant current driver 230E to the full-on state, and turns off the second switch SW2. When the switching terminal SEL is set to the second state, the switching circuit 220 sets the second constant current driver 230E to the constant current state, and turns on the second switch SW2.
With the embodiment 2, as with the embodiment 1, in the first lighting mode, this allows the first semiconductor light source 101 and the second semiconductor light source 102 to emit light brightly using the first driving current IOUT1. Furthermore, in the second lighting mode, this allows the first semiconductor light source 101 and the third semiconductor light source 103 to emit light brightly using the first driving current IOUT1, and allows the second semiconductor light source 102 to emit light using the second driving current IOUT2 more dimly than in the first lighting mode.
The switching circuit 220 controls the second switch SW2 and the current driver 230E according to the state of the switching terminal SEL. In this example, when the switching terminal SEL is set to the first state (high impedance, low), the switching circuit 220 outputs the high-level inverted enable signal ENB, and outputs a low-level signal to the gate of the second switch SW2. When the switching terminal SEL is set to the second state (high), the switching circuit 220 outputs the low-level inverted enable signal ENB, and outputs a high-level signal to the gate of the second switch SW2. The switching circuit 220 includes an inverter 222.
When the switching terminal SEL is set to the first state, the high-level inverted enable signal EN is input to the second constant current driver 230E. When the inverted enable signal EN is set to the high level, the gate of the first transistor M31 is fixed to the high level, which disables the feedback circuit 240. In this state, the first transistor M31, i.e., the second constant current driver 230E is set to the full-on state. Furthermore, the second switch SW2 is turned off. Accordingly, the lighting mode is set to the first lighting mode.
When the switching terminal SEL is set to the second state, the low-level inverted enable signal EN is input to the second constant current driver 230E. In this state, the feedback circuit 240 is activated, so as to set the second constant current driver 230E to a constant current state. In the constant current state, the second driving current IOUT2 is stabilized to IOUT2=VREF/R31. In this case, the second switch SW2 is turned on. Accordingly, the lighting mode is set to the second lighting mode.
Description will be made regarding modifications relating to the embodiment 2.
In the second lighting mode, the first constant current driver 210 may increase the first driving current IOUT1 as compared with that in the first lighting mode.
As described in the modifications 1.5 (
The switch control circuit 260 includes a pulse width modulator 262 and an inverter 264. When the switching terminal SEL is set to the first state (low level, high impedance), the pulse width modulator 262 outputs a high-level signal. When the switching terminal SEL is set to the second state (high level), the pulse width modulator 262 outputs the pulse signal Spwm. The output of the pulse width modulator 262 is supplied to the first switch SW1. Furthermore, the output of the pulse width modulator 262 is inverted by the inverter 264, and the inverted signal is supplied to the second switch SW2.
The pulse width modulator 262 includes a voltage generator 266, a comparator COMP1, and an oscillator 268. In the first state, the voltage generator 266 generates the voltage Vd of 0 V. In the second state, the voltage generator 266 generates the voltage Vd having a predetermined level. The oscillator 268 generates a cyclic signal VRAMP configured as a ramp wave or a triangle wave. The comparator COMP1 compares the voltage Vd with the cyclic signal VRAMP.
In the first state, the output of the comparator COMP1 is fixed to the high level. In the second state, as the output of the comparator COMP1, the pulse signal Spwm is output with a duty cycle d1 that corresponds to the voltage Vd.
The voltage generator 266 includes resistors R41 through R43 and transistors Q41 and Q42. When the switching terminal SEL is set to the first state (low level, high impedance), the transistor Q42 is turned off and the transistor Q41 is turned on. In this state, the voltage Vd is set to 0 V. When the switching terminal SEL is set to the second state (high level), the transistor Q42 is turned on and the transistor Q41 is turned off. With this, the voltage Vd is set to a voltage obtained by dividing the power supply voltage Vcc by the resistors R41 and R42.
Description will be made regarding the operation of the automotive lamp 100F shown in
When the switching terminal SEL is set to the first state (low level), the switch control circuit 260 generates the pulse signal Spwm having a duty cycle d1 that is smaller than 50%, so as to drive the transistor M41. Furthermore, the transistor M42 is driven by the inverted signal of the pulse signal Spwm. The first driving current IOUT1 generated by the first constant current driver 210 flows through the second semiconductor light source 102 during a period of Tp×d1, and flows through the third semiconductor light source 103 during a period of Tp×(1−d1) after the first driving current IOUT1 flows through the first semiconductor light source 101. Here, Tp represents the period of the pulse signal Spwm. In this arrangement, d1 is designed such that d1<50% holds true. Accordingly, the semiconductor light source 102 emits light relatively dimly. In contrast, the semiconductor light source 103 emits light relatively brightly. With this, the second lighting mode is supported.
Description will be made regarding modifications relating to the embodiment 3.
In the second lighting mode, the first constant current driver 210 may increase the first driving current IOUT1 as compared with that in the first lighting mode.
As described in the modifications 1.5 (
The automotive lamp 400 includes a main input terminal VIN, a switching terminal SEL, and a ground terminal GND. The ground GND is grounded. The input terminal VIN receives the supply of a voltage V BAT from a battery 2 via a switch 4 arranged on the vehicle side. On the vehicle side, upon turning on a lighting switch for a headlamp by the driver, the switch 4 is turned on, which supplies a power supply voltage VIN to the input terminal VIN. The power supply voltage VIN has two functions, i.e., a function as a power supply voltage for the automotive lamp 400 and a function as a lighting instruction.
Furthermore, the electrical state of the switching terminal SEL of the automotive lamp 400 is switched between the first state and the second state according to the lighting mode of the automotive lamp 400. In the present embodiment, the first state is a no-input (high-impedance) state. The second state is a state in which a non-zero voltage is input. Specifically, the switching terminal SEL is coupled to the battery 2 via a switch 6 arranged on the vehicle side. On the vehicle side, when the driver selects the low-beam mode (first lighting mode), the switch 6 is turned off so as to set the switching terminal SEL to a no-input (high-impedance) state. When the driver selects the high-beam mode (second lighting mode), the switch 6 is turned on so as to supply a switching voltage VSEL having a high level (battery voltage) to the switching terminal SEL.
The automotive lamp 400 is configured as a lamp module that is switchable between the high-beam mode and the low-beam mode. The automotive lamp 400 includes a first semiconductor light source 101, a second semiconductor light source 102, a third semiconductor light source 103, and a lighting circuit 500. The first semiconductor light source 101, the second semiconductor light source 102, and the third semiconductor light source 103 are each configured as a white light-emitting diode (LED), for example.
The first semiconductor light source 101 through the third semiconductor light source 103 are coupled such that the current that flows through the first semiconductor light source 101 is the sum total of the currents that flow through the second semiconductor light source 102 and the third semiconductor light source 103. Specifically, the first semiconductor light source 101 is coupled between a first node n1 and a second node n2. The second semiconductor light source 102 is coupled between the second node n2 and a third node n3 so as to form a first path. The third semiconductor light source 103 is coupled between the second node n2 and the third node n3 so as to form a second path that is parallel to the first path.
The lighting circuit 500 drives the first semiconductor light source 101 through the third semiconductor light source 103. In the first lighting mode (low-beam mode), the lighting circuit 500 turns on the first semiconductor light source 101 and the second semiconductor light source 102, and turns off the third semiconductor light source 103. In the second lighting mode, the lighting circuit 500 turns on the first semiconductor light source 101 and the third semiconductor light source 103, and turns on the second semiconductor light source 102 so as to be dimmer than the first lighting mode. The first semiconductor light source 101 is preferably operated to provide almost no change in brightness between the first lighting mode and the second lighting mode.
The lighting circuit 500 includes a first constant current driver 210, a switching circuit 220, a first switch SW1, a second switch SW2, and a bypass circuit 270.
The first constant current driver 210 has its output node OUT coupled to the anode (first node n1) of the first semiconductor light source 101. When the power supply voltage VIN is supplied to the input terminal VIN, the first constant current driver 210 is activated, and outputs a first driving current IOUT1. The first constant current driver 210 may be configured as a buck converter that outputs a constant current. Also, the first constant current driver 210 may be configured as a constant current output linear regulator or other kinds of constant current circuits.
In the present embodiment, the third node n3, i.e., the cathode of the second semiconductor light source 102 and the cathode of the third semiconductor light source 103 are grounded. The first switch SW1 is arranged between the cathode (second node n2) of the first semiconductor light source 101 and the anode of the second semiconductor light source 102. The second switch SW2 is arranged between the cathode (second node n2) of the first semiconductor light source 101 and the anode of the third semiconductor light source 103.
In the first state (high impedance, no input) of the switching terminal SEL, the switching circuit 220 turns on the first switch SW1 and turns off the second switch SW2. On the other hand, in the second state of the switching terminal SEL, i.e., when the switching voltage VSEL is supplied, the switching circuit 220 turns off the first switch SW1 and turns on the second switch SW2.
In the first lighting mode or the second lighting mode, in order to turn on two semiconductor light sources arranged in series between the first node n1 and the third node n3, it is necessary to apply a voltage that is higher than (Vf×2) between the first node n1 and the third node n3. That is to say, the first constant current driver 210 is required to output an output voltage VOUT that is higher than VOUT(TH)=2×Vf. Here, Vf represents the forward voltage of the semiconductor light source. In a case in which the first constant current driver 210 is configured as a linear regulator or a buck converter, the output voltage VOUT thereof is lower than the power supply voltage VIN. Accordingly, in a case in which the power supply voltage VIN is lower than a predetermined threshold voltage VIN(TH), the output voltage VOUT is lower than the threshold voltage VOUT(TH). In this case, the semiconductor light sources turn off. In order to solve this problem, the bypass circuit 270 is provided.
The bypass circuit 270 includes a bypass switch SW3 and a low-voltage detection circuit 280. The bypass switch SW3 is provided between the second node n2 and the third node n3. In a state in which the power supply voltage VIN is lower than the predetermined threshold value VIN(TH), the low-voltage detection circuit 280 turns on the bypass switch SW3. In a state in which the power supply voltage VIN is higher than the predetermined threshold value VIN(TH), the low-voltage detection circuit 280 turns on the bypass switch SW3.
Preferably, the threshold voltage VIN(TH) is provided with hysteresis. In this case, two threshold voltages VTHL and VTHH (note that VTHL<VTHH) are defined for the low-voltage detection circuit 280. The low-voltage detection circuit 280 compares the power supply voltage VIN with the first threshold voltage VTHL and the second threshold voltage VTHH. When VIN<VTHL is detected, the low-voltage detection circuit 280 turns on the bypass switch SW3. When VIN>VTHH is detected, the low-voltage detection circuit 280 turns off the bypass switch SW3.
The above is the configuration of the automotive lamp 400. Next, description will be made regarding the operation thereof.
Normal Voltage State
Referring to
Referring to
Low-Voltage State
Referring to
Referring to
The above is the operation of the automotive lamp 400.
With the automotive lamp 400, in the low-voltage state, the bypass switch SW3 is turned on. This allows the emission of light from the first semiconductor light source 101 to be maintained regardless of the lighting mode.
The first semiconductor light source 101 is preferably configured as a light source that illuminates the low-beam diffusion region A1 shown in
As a comparison technique, let us consider an arrangement in which the bypass switch SW3 is provided in parallel with the first semiconductor light source 101, i.e., is provided between the first node n1 and the second node n2. In such a comparison technique, when the low-voltage state occurs, in the first lighting mode (low-beam mode), only the low-beam focusing region A2 is illuminated. Furthermore, in this case, in the second lighting mode (high-beam mode), only the high-beam region A3 is illuminated. With the comparison technique, in the second lighting mode in the low-voltage state, only a distant region is illuminated brightly. In contrast, the low-beam diffusion region A1 closer to the user's vehicle becomes dim. In contrast, with the embodiment, this is capable of forming a preferable light distribution in the low-voltage state as compared with such a comparison technique.
When the switching terminal SEL is set to the first state (no-input state, low level, high-impedance state), the switching circuit 220 sets the control terminal of the first switch SW1 to the high-level state, and sets the control terminal of the second switch SW2 to the low-level state. Conversely, when the switching terminal SEL is set to the second state (high level (VSEL=VBAT)), the switching circuit 220 sets the control terminal of the first switch SW1 to the low-level state, and sets the control terminal of the second switch SW2 to the high-level state.
That is to say, the switching circuit 220 supplies the first output S1 having a logical value complementary to the signal applied to the switching terminal SEL to the first switch SW1. Furthermore, the switching circuit 220 supplies the second output S2 having the same logical value as that of the signal applied to the switching terminal SEL to the second switch SW2.
The switching circuit 220 includes transistors Q11 through Q14 and a resistor R4. When the switching terminal SEL is set to the low level or the high-impedance state, the transistor Q11 is turned off, the transistor Q12 is turned off, and the transistor Q14 is turned on. The high-level signal S1 is input to the control terminal of the first switch SW1. In this state, the transistor Q13 is turned off. Accordingly, the control terminal of the second switch SW2 is set to the low-level state.
Conversely, when the switching terminal SEL is set to the high-level state, the transistor Q11 is turned on, the transistor Q12 is turned on, and the transistor Q14 is turned off. Accordingly, the control terminal of the first switch SW1 is set to the low-level state. In this state, the transistor Q13 is turned on. Accordingly, the control terminal of the second switch SW2 is set to the high-level state.
It can be understood by those skilled in this art that the configurations of the first switch SW1, the second switch SW2, the switching circuit 220, and the second constant current driver 230 are not restricted to those shown in
The bypass switch SW3 includes a third transistor M3 configured as an N-channel MOSFET. The low-voltage detection circuit 280 is configured as a hysteresis comparator, including transistors Q51 and Q52, resistors R51 through R53, and a Zener diode ZD51.
Let us consider a state in which the transistor Q52 is turned off, and accordingly, the low-voltage detection circuit 280 outputs a high-level (H) output signal. In this state, the transistor Q51 is turned on. Accordingly, the voltage Vx at a connection node that couples the resistors R51 and R52 is represented by Vx=(VIN−VZE)×R52/(R51+R52). When the voltage Vx is lower than the threshold voltage (0.6 to 0.7 V) of the transistor Q52, the transistor Q52 remains off, and the low-voltage detection circuit 280 outputs a high-level signal.
When the voltage Vx exceeds the threshold voltage (0.6 to 0.7 V) of the transistor Q52, the transistor Q52 turns on, and the low-voltage detection circuit 280 outputs a low-level signal.
Let us consider a state in which the transistor Q52 is turned on, and the low-voltage detection circuit 280 outputs a low-level (Low) signal. In this state, the transistor Q51 is turned off, and accordingly, the voltage at a connection node that couples the resistors R51 and R52 is represented by Vx=(VIN−VZD). Description will be made assuming that the transistor Q52 has a sufficiently high base resistance.
When the voltage Vx is higher than the threshold voltage (0.6 to 0.7 V) of the transistor Q52, the transistor Q52 remains on, and the low-level detection circuit 280 outputs a low-level signal.
When the voltage Vx becomes lower than the threshold voltage (0.6 to 0.7 V) of the transistor Q52, the transistor Q52 is turned off, and the low-voltage detection circuit 280 outputs a high-level signal.
The configuration of the low-voltage detection circuit 280 is not restricted to that shown in
The second constant current driver 230 is coupled to the switching terminal SEL. When the switching voltage VSEL is supplied to the switching terminal SEL, the second constant current driver 230 becomes active, and supplies a second driving current IOUT2 that is smaller than the first driving current IOUT1 to the anode of the second semiconductor light source 102. The second driving current IOUT2 may preferably be determined to the extent that, in the second state, a region including the second semiconductor light source 102 can be visible as being turned on when viewed from the exterior of the automotive lamp 400. For example, the second driving current IOUT2 may preferably be determined to be larger than 10 mA.
The above is the configuration of the automotive lamp 400. Next, description will be made regarding the operation thereof.
Referring to
Referring to
Furthermore, the second driving current IOUT2 generated by the second constant current driver 230 flows through the second semiconductor light source 102. Accordingly, the second semiconductor light source 102 remains turned on. However, the light intensity thereof is reduced as compared with that in the first lighting mode.
The above is the operation of the automotive lamp 400.
With the automotive lamp 400, when the lighting mode is switched from the first lighting mode (low-beam mode) to the second lighting mode (high-beam mode), the third semiconductor light source 103 is additionally turned on in a state in which the second semiconductor light source remains turned on. Accordingly, this is capable of preventing a portion that had been bright from suddenly becoming dim immediately after the mode switching as viewed from the surroundings of the automotive lamp 400, thereby providing an improved appearance.
Furthermore, with the automotive lamp 400, even in the second lighting mode, the second semiconductor light source remains turned on. Accordingly, this is capable of preventing the intensity of a region illuminated by the second semiconductor light source 102 on a virtual vertical screen from changing significantly.
For example, let us consider an arrangement in which the optical system of the automotive lamp 400 is designed such that the output light of the first semiconductor light source 101, the second semiconductor light source 102, and the third semiconductor light source 103 are respectively emitted to the regions A1, A2, and A3 shown in
In this case, in a case in which the second semiconductor light source 102 is designed to be turned off in the second lighting mode, the region A2 becomes dim. In particular, in this state, the region L2 is not illuminated by any one of the light sources. In contrast, with the present embodiment, the second semiconductor light source 102 remains turned on in the second lighting mode. Accordingly, in this state, light is emitted to the region A2, thereby suppressing an unnatural change in the light distribution.
Furthermore, in the second lighting mode, the driving current IOUT2 that flows through the second semiconductor light source 102 is smaller than the driving current IOUT1 that flows through in the first lighting mode. Accordingly, this involves only a slight increase in the heat generation (power consumption) due to the second semiconductor light source 102 remaining turned on. Accordingly, there is no need to apply an additional heat-generation countermeasure. Alternatively, such an arrangement requires only a minor countermeasure. This is capable of suppressing an increase in cost.
Furthermore, by designing the amount of the second driving current IOUT2 to be larger than 10 mA, this allows a contact current exceeding 10 mA required to prevent oxidation of the connector terminal to flow through the switching terminal SEL. That is to say, the driving current IOUT2 of the second semiconductor light source 102 also has a function for preventing oxidation, thereby suppressing an increase in unnecessary power consumption.
I
OUT2=(VSEL−Vf2−Vff3)/R3=(VBAT−Vf2−Vf3)/R3
That is to say, the amount of the second driving current IOUT2 can be determined according to the resistance value of the current-limiting resistor R3. Furthermore, with such an arrangement provided with the diode D3, this is capable of preventing the first driving current IOUT1 generated by the first constant current driver 210 from flowing into the switching terminal SEL or the switching circuit 220. It should be noted that, in a case in which the switching circuit 220 has a sufficiently high input impedance, the diode D3 may be omitted.
In
In this modification, the first switch SW1 further includes a capacitor C1. One end of the capacitor C1 is coupled to the drain (or collector) of the transistor M1. The other end of the capacitor C1 is coupled to the control terminal (i.e., gate or base) of the switching transistor M1.
Description will be made regarding the turn-on operation of the switch SW1. When the gate voltage VG increases to the vicinity of the gate-source threshold voltage VGS(th) of the transistor M1, the rate of increase of the gate voltage VG becomes very slow due to the Miller effect caused by the capacitor C1. This allows the switch SW1 to be gradually turned on.
The same can be said of the turn-off operation. When the gate voltage VG decreases to the vicinity of the gate-source threshold voltage VGS(th) of the transistor M1, the rate of decrease of the gate voltage VG becomes very slow due to the Miller effect caused by the capacitor C1. This allows the switch SW1 to be gradually turned off.
With such an arrangement in which the capacitor C1 is additionally provided to the first switch SW1 (and the second switch SW2), this is capable of gradually turning on and off the switch. This allows the light intensities of the second semiconductor light source 102 and the third semiconductor light source 103 to be gradually changed. That is to say, this supports gradual turn-on and gradual turn-off. Furthermore, this is capable of preventing a sudden change in the electric potential at the anode or the cathode of each of the first semiconductor light source 101 through the third semiconductor light source 103.
Furthermore, in
If there is an off section in which both the first switch SW1 and the second switch SW2 are turned off, the first constant current driver 210 enters a no-load state. This leads to an increase in the output voltage VOUT, resulting in an overvoltage state. When the first switch SW1 or the second switch SW2 is turned on in a state in which the output voltage VOUT increases, overcurrent flows through the LED. In contrast, with such an arrangement shown in
When the high-side transistor MP of the output stage of the switching circuit 220 is turned on, the gate of the transistor M1 is charged via a parallel connection circuit formed of the resistors R11 and R13, thereby raising the gate voltage VG.
When the low-side transistor MN of the output stage of the switching circuit 220 is turned on, the gate of the transistor M1 is discharged via the resistor R11, thereby reducing the gate voltage VG.
With this, there is a difference in impedance between the charging path and the discharging path. Accordingly, the gate voltage V G increases at a rate that is higher than a rate at which the gate voltage V G decreases. This allows the first switch SW1 to be turned on in a short period of time and to be turned off slowly. That is to say, this allows the light intensity of the second semiconductor light source 102 to be gradually reduced (gradual turn-off). The same can be said of the third semiconductor light source 103.
With the configuration shown in
The first switch SW1 shown in
When the high-side transistor MP of the output stage of the switching circuit 220 is turned on, the gate of the transistor M1 is charged via a parallel connection circuit formed of the resistors R11 and R13, thereby raising the gate voltage VG. When the low-side transistor MN of the output stage of the switching circuit 220 is turned on, the gate of the transistor M1 is discharged via the resistor R11, thereby lowering the gate voltage VG.
When the control signal S1 is set to the low level, the transistor M11 is turned on, and accordingly, the gate of the transistor M1 is charged via the resistor R11. In this state, the gate voltage VG increases, thereby turning on the transistor M1. Conversely, when the control signal S1 is set to the high level, the transistor M12 is turned on, and accordingly, the gate of the transistor M1 is discharged via the resistors R11 and R14. In this state, the gate voltage VG decreases, thereby turning off the transistor M1.
With this, there is a difference in impedance between the charging path and the discharging path. Accordingly, the gate voltage VG increases at a rate that is higher than a rate at which the gate voltage VG decreases. As with the arrangements shown in
With the configuration shown in
Furthermore, with the configuration shown in
Components of the lighting circuit 500 and a connector 144 are mounted on a printed circuit board 142. The connector 144 includes three terminals, i.e., an input terminal VIN, a switching terminal SEL, and a ground terminal GND. The wiring of the printed circuit board 142 is coupled to the electrodes of the first semiconductor light source 101 through the third semiconductor light source 103 via bonding wires. It should be noted that the printed circuit board 142 may be omitted. In this case, the components of the lighting circuit 500 and the connector 144 may be directly mounted on the radiator plate 146. Furthermore, in the present embodiment, the heat generation of the automotive lamp 400 is reduced. Accordingly, the radiator plate 146 having a thin thickness may be employed. However, instead of such a thin radiator plate 146, a heat sink having a large thickness may be employed. The connector 144 is not restricted to such a connector to be mounted. Also, other types of connectors such as a card edge connector or the like may be employed.
A lens module 150 includes a first lens 151, a second lens 152, and a third lens 153. The first lens 151 receives the output beam of the first semiconductor light source 101, and projects the output beam to a low-beam diffusion region A1. The second lens 152 receives the output beam of the second semiconductor light source 102, and projects it to a low-beam focusing region A2. The third lens 153 receives the output beam of the third semiconductor light source 103, and projects it to a high-beam region A3.
Next, description will be made regarding modifications relating to the embodiment 5.
With this modification, the same effects can be obtained as those of the automotive lamp 400 shown in
With the automotive lamp 400B, in the second lighting mode, this is capable of preventing the illumination region of the semiconductor light source 102 from becoming significantly dimmer in the second lighting mode.
It should be noted that, in the automotive lamp 400B, the switching terminal SEL has a high impedance. Accordingly, during the second lighting mode, almost no contact current flows. Accordingly, in order to prevent oxidation of the connector terminal, there is a need to additionally provide an arrangement configured to flow contact current. In other words, with an arrangement configured to supply the power supply voltage of the second constant current driver 230 from the switching terminal SEL, i.e., with an arrangement in which the second driving current IOUT2 is supplied from the switching terminal SEL, the operating current of the second constant current driver 230 continuously flows during the second lighting mode. Such arrangement requires no additional configuration for preventing oxidation of the connector terminal.
The positions of the second switch SW2 and the third semiconductor light source 103 may be interchanged.
Each bipolar transistor may be replaced by a Metal Oxide Semiconductor Field Effect Transistor (MOSFET). In this case, the base, collector, and emitter correspond to the gate, drain, and source, respectively. Also, each NPN (N-channel) transistor may be replaced by a PNP (P-channel) transistor.
With this modification, in the second lighting mode, the current IOUT2 generated by the second constant current driver 230A flows through the first semiconductor light source 101 in addition to the second semiconductor light source 102. This is the point of difference from the arrangement shown in
With this modification, in the second lighting mode, the current IOUT2 generated by the second constant current driver 230A flows through the first semiconductor light source 101 in addition to the second semiconductor light source 102. This is the point of difference from the arrangement shown in
A second constant current driver 230H is coupled in parallel with the first switch SW1. In the first lighting mode, the switching circuit 220 turns on the first switch SW1 and turns off the second switch SW2. In the second lighting mode, the switching circuit 220 turns off the first switch SW1 and turns on the second switch SW2.
When the switching terminal SEL is set to the first state, the second constant current driver 230H is disabled. On the other hand, when the switching terminal SEL is set to the second state, the second constant current driver 230H is enabled. In this state, the second constant current driver 230H generates the second driving current IOUT2.
The second constant current driver 230E is coupled between the third node n3 and the second semiconductor light source 102 on the first path. The second constant current driver 230E is configured to be switchable between a full-on state and a constant current state in which the second driving current IOUT2 that is smaller than the first driving current IOUT1 is generated. The full-on state is a state in which the impedance is set to a very small value, which corresponds to the on state of the first switch SW1.
When the switching terminal SEL is set to the first state, the switching circuit 220 sets the second constant current driver 230E to the full-on state, and turns off the second switch SW2. When the switching terminal SEL is set to the second state, the switching circuit 220 sets the second constant current driver 230E to the constant current state, and turns on the second switch SW2.
With the embodiment 6, as with the embodiment 5, in the first lighting mode, this allows the first semiconductor light source 101 and the second semiconductor light source 102 to emit light brightly using the first driving current IOUT1. Furthermore, in the second lighting mode, this allows the first semiconductor light source 101 and the third semiconductor light source 103 to emit light brightly using the first driving current IOUT1, and allows the second semiconductor light source 102 to emit light using the second driving current IOUT2 more dimly than in the first lighting mode.
The switching circuit 220 controls the second switch SW2 and the current driver 230E according to the state of the switching terminal SEL. In this example, when the switching terminal SEL is set to the first state (high impedance, low), the switching circuit 220 outputs the high-level inverted enable signal ENB, and outputs a low-level signal to the gate of the second switch SW2. When the switching terminal SEL is set to the second state (high), the switching circuit 220 outputs the low-level inverted enable signal ENB, and outputs a high-level signal to the gate of the second switch SW2. The switching circuit 220 includes an inverter 222.
When the switching terminal SEL is set to the first state, the high-level inverted enable signal EN is input to the second constant current driver 230E. When the inverted enable signal EN is set to the high level, the gate of the first transistor M31 is fixed to the high level, which disables the feedback circuit 240. In this state, the first transistor M31, i.e., the second constant current driver 230E is set to the full-on state. Furthermore, the second switch SW2 is turned off. Accordingly, the lighting mode is set to the first lighting mode.
When the switching terminal SEL is set to the second state, the low-level inverted enable signal EN is input to the second constant current driver 230E. In this state, the feedback circuit 240 is activated, so as to set the second constant current driver 230E to a constant current state. In the constant current state, the second driving current IOUT2 is stabilized to IOUT2=VREF/R31. In this case, the second switch SW2 is turned on. Accordingly, the lighting mode is set to the second lighting mode.
Description will be made regarding modifications relating to the embodiment 6.
In the second lighting mode, the first constant current driver 210 may increase the first driving current IOUT1 as compared with that in the first lighting mode.
As described in the modifications 5.5 (
The switch control circuit 260 includes a pulse width modulator 262 and an inverter 264. When the switching terminal SEL is set to the first state (low level, high impedance), the pulse width modulator 262 outputs a high-level signal. When the switching terminal SEL is set to the second state (high level), the pulse width modulator 262 outputs the pulse signal Spwm. The output of the pulse width modulator 262 is supplied to the first switch SW1. Furthermore, the output of the pulse width modulator 262 is inverted by the inverter 264, and the inverted signal is supplied to the second switch SW2.
The pulse width modulator 262 includes a voltage generator 266, a comparator COMP1, and an oscillator 268. In the first state, the voltage generator 266 generates the voltage Vd of 0 V. In the second state, the voltage generator 266 generates the voltage Vd having a predetermined level. The oscillator 268 generates a cyclic signal VRAMP configured as a ramp wave or a triangle wave. The comparator COMP1 compares the voltage Vd with the cyclic signal VRAMP.
In the first state, the output of the comparator COMP1 is fixed to the high level. In the second state, as the output of the comparator COMP1, the pulse signal Spwm is output with a duty cycle d1 that corresponds to the voltage Vd.
The voltage generator 266 includes resistors R41 through R43 and transistors Q41 and Q42. When the switching terminal SEL is set to the first state (low level, high impedance), the transistor Q42 is turned off and the transistor Q41 is turned on. In this state, the voltage Vd is set to 0 V. When the switching terminal SEL is set to the second state (high level), the transistor Q42 is turned on and the transistor Q41 is turned off. With this, the voltage Vd is set to a voltage obtained by dividing the power supply voltage Vcc by the resistors R41 and R42.
Description will be made regarding the operation of the automotive lamp 400F shown in
When the switching terminal SEL is set to the first state (low level), the switch control circuit 260 generates the pulse signal Spwm having a duty cycle d1 that is smaller than 50%, so as to drive the transistor M41. Furthermore, the transistor M42 is driven by the inverted signal of the pulse signal Spwm. The first driving current IOUT1 generated by the first constant current driver 210 flows through the second semiconductor light source 102 during a period of Tp×d1, and flows through the third semiconductor light source 103 during a period of Tp×(1−d1) after the first driving current IOUT1 flows through the first semiconductor light source 101. Here, Tp represents the period of the pulse signal Spwm. In this arrangement, d1 is designed such that d1<50% holds true. Accordingly, the semiconductor light source 102 emits light relatively dimly. In contrast, the semiconductor light source 103 emits light relatively brightly. With this, the second lighting mode is supported.
Description will be made regarding modifications relating to the embodiment 7.
In the second lighting mode, the first constant current driver 210 may increase the first driving current IOUT1 as compared with the first lighting mode.
As described in the modifications 5.5 (
Description has been made above regarding the embodiments. The above-described embodiments have been described for exemplary purposes only. Rather, it can be readily conceived by those skilled in this art that various modifications may be made by making various combinations of the aforementioned components or processes, which are also encompassed in the technical scope of the present invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2021-073626 | Apr 2021 | JP | national |
| 2021-122718 | Jul 2021 | JP | national |
| 2021-122719 | Jul 2021 | JP | national |
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/JP2022/018483 | Apr 2022 | US |
| Child | 18487376 | US |
