Many light emitting devices use drivers to drive light emitters, such as light emitting diodes (LEDs) or other light sources. The forward voltage of LEDs varies with temperature and possibly other factors. As the forward voltage increases, the voltage required to be supplied by the drivers to drive the LEDs increases. In many devices, the voltage required by the LEDs can increase beyond the capability of the drivers. The result is low intensity light emission or no light emission.
An embodiment of a light emitting device 100 is shown in
The LEDs 104 emit light when forward current is passed through them. A forward voltage is required to be applied to the LEDs 104 in order to generate a forward current. The forward voltage of the LEDs 104 may vary due to temperature and other variables. Thus, the voltage supplied by the driver 106 may have to increase in order to accommodate the increased forward voltage requirements. In conventional light emitting devices, the forward voltage of the LEDs may exceed the maximum output of the driver, which will cause the illumination of the LEDs 104 to diminish or may cause the LEDs to stop illuminating.
The driver 106 has a plurality of channels 110 wherein each channel is capable of driving a plurality of series LEDs. In the embodiment of the driver 106 described herein, the driver 106 has six channels 110 designated as channel 1 through channel 6. It is noted that the driver 106 may have any number of channels greater than one. The channels may be considered to be individual drivers and may be referenced herein as individual drivers. The channels 110 maintains a forward current through the LEDs 104 by adjusting their output voltage. However, the maximum voltage able to be output by the channels 110 is dependent on the supply voltage of the driver 106 along with other variables. Therefore, situations may arise wherein a channel voltage may not be able to be high enough to supply adequate current to illuminate series LEDs. The light emitting device 100 overcomes this problem as described below.
The LEDs 104 are connected in series, wherein some of the series connections may be in parallel with one another. The series connections of LEDs 104 are referred to herein as strings or pluralities of LEDs. The embodiment of the light emitter 100 of
Each string has a first group 130 of LEDs and a second group 132 of LEDs. In the embodiment of
Channels 1-5 are connected to a comparator 136. It is noted that channel 6 is not connected to the comparator 136 or a string. The function of channel 6 will be described in greater detail below. The comparator 136 serves to determine if a channel voltage exceeds a predetermined value. In the embodiment of
Referring to the first string 120, which is substantially similar to the second through fourth strings 122-126, a first switch 142 is connected between a node 144 and ground. The first switches 142 are normally open. The term normally as referred to herein refers to a state of the light emitting device 100 when none of the channel voltages exceed the predetermined value. Accordingly, the switch 138 outputs the first voltage. The state of the first switches 142 are controlled by the switch 138. When the switch 138 outputs the first voltage, the first switches 142 are open. Likewise, when the switch 138 outputs the second voltage, the first switches 142 close.
Second switches 148 are connected between the first node 144 and the second group 132 of LEDs. Like the first switches 142, the second switches 148 are controlled by the output voltage of the switch 138. However, the second switches 148 are in the opposite state of the first switches 142. Therefore, when the switch 138 outputs the first voltage, the second switches 148 are closed. When the switch 138 outputs the second voltage, the second switches 148 are open.
Third switches 150 are connected between the second group 132 and ground and connect the second group 132 to ground when the third switches 150 are closed. When the third switches 150 are closed, the strings 120-128 consist of the first group 130 and the second group 132 of LEDs. As described in greater detail below, when the third switches 150 are open, the second group 132 of LEDs may form a sixth string. It is noted that the fifth string 238 does not have a third switch 150 associated therewith. As with the first switches 142 and the second switches 148, the third switches 150 are controlled by the switch 138. The third switches 150 are normally closed and are in the same state as the second switches 148.
Fourth switches 154 are connected between the strings 120-128. The fourth switches 154 are controlled via the switch 138 and are in an opposite state relative to the third switches 150. Therefore, when the third switches 150 are closed, the fourth switches 154 are open. It is noted that when the fourth switches 154 are closed, the anode of an LED on one string is connected to the cathode of an LED in another string.
A fifth switch 158 connects the sixth channel to the second group 132 of LEDs. In the embodiment of
Having described the components of the light emitting device 100, the operation of the light emitting device 100 will now be described. In summary, the light emitting device 100 maintains all the LEDs 104 with enough forward voltage and/or current to remain illuminating when the forward voltage of one or more of the LEDs 104 increases. Thus, the intensity of light emitted by the light emitting device 100 remains substantially constant.
The embodiment of the light emitter 100 of
In this first state, five strings 120-128 of LEDs 104 are connected to channels 1-5, wherein each of the five strings 120-128 consists of the first group 130 and the second group 132 of LEDs connected in series. In this state, each LED has a forward voltage that is low enough that to assure that all the LEDs 104 are able to produce light.
Events may occur that cause the forward voltage of one or more of the LEDs 104 to increase. For example, the temperature of the LEDs 104 may change the forward voltage. In order to meet the forward voltage requirements of the LEDs 104, the driver 106 outputs higher voltages on one or more of the channels 1-5. The output voltages of the channels 1-5 are monitored by the comparator 136 where they are compared to a predetermined voltage. The predetermined voltage may be close to the maximum voltage that the driver 106 or an individual channel is able to output. When this channel voltage is equal to or greater than the predetermined voltage, the comparator 136 changes. This voltage change causes the output 140 of the switch 138 to toggle from the first voltage to the second voltage.
When the switch 138 outputs the second voltage, the switches change state, which yields the circuit of
In the second state, the third switches 150 are open and the fourth switches 154 are closed. In addition, the fifth switch 158 is closed. In the second state, the LEDs in the second group 132 are connected in series and powered by channel 6 of the driver 106. As shown in
The light emitter 100 has been described as using LEDs 104. However, the use of LEDs is for illustration and other light sources may be used. The light emitter 100 has been described as using switches 142, 148, 150, 154,158. Many different embodiment of switches may be used. For example, field effect transistors (FETs) or other electronic switches may be used. The comparator 136 described above compares each channel voltage to the predetermined voltage. In other embodiments, the comparator 136 may compare fewer channel voltages to the predetermined voltage. The switch 138 has been described as an exclusive NOR gate. In other embodiments, different devices may be used. For example, an OR gate may be used. In other embodiments, one channel voltage may be monitored and the output of the comparator 136 may be used to toggle the switches instead of using the switch 138.