CN209803548U - Electronic device - Google Patents

Abstract

The utility model provides an electronic device. The electronic device comprises a system power supply unit, a system control unit, a laser power supply unit, a laser unit and a laser current monitoring unit. The system power supply unit is used for supplying power. The system control unit is used for sending a first current control signal to the laser power supply unit. The laser power supply unit is used for providing current to the laser unit through a first current path according to a first current control signal, wherein the current flows back to the laser power supply unit through a second current path. The laser current monitoring unit is connected in series with the current value of the continuous current on the first current path. If the current value of the current is larger than the preset threshold value, the laser current monitoring unit sends a second current control signal so as to reduce the current value of the current or stop the current from being provided to the laser unit. The utility model provides an electronic device can avoid providing too big electric current to the laser unit in the electronic device efficiently.

Description

Electronic device

Technical Field

The present invention relates to an apparatus, and more particularly, to an electronic apparatus.

background

FIG. 6 is a block diagram of a projector according to the prior art. Referring to fig. 6, a conventional projector (e.g., a laser projector) includes a system control unit, a system power supply unit, a laser power supply circuit, a laser current control and feedback unit, and a laser circuit. Specifically, the laser unit provides a current feedback signal SB to the laser current control and feedback circuit, so that the laser current control and feedback circuit transmits a current control signal SC to the laser power supply circuit, thereby controlling the current provided by the laser power supply circuit to the laser unit; or the laser unit provides a current feedback signal SB to the laser current control and feedback circuit, so that the laser current control and feedback circuit transmits the current feedback signal SB to the system control unit, and further the system power supply unit is controlled to continue or stop providing current or voltage to the laser power supply circuit.

in addition, the laser power supply unit and the laser current control and feedback unit can be integrated into the same unit (as shown in fig. 6 as 1), i.e., the laser power supply unit provides current to the laser unit through one path, and receives the current feedback signal SB generated by the laser unit through the other path. Therefore, the laser power supply unit directly receives the current feedback signal SB to adjust the magnitude of the current value of the supplied current.

However, in the conventional laser projector, only the system control unit and the laser power supply unit are used to perform feedback control, such as overcurrent monitoring or overcurrent cutoff, on the current supplied to the laser unit. However, when the system control unit or the laser power supply unit fails, the current value provided by the laser power supply unit to the laser unit exceeds the load of the laser unit, so that the laser unit emits laser with too high intensity. In this case, the laser unit may be damaged by the excessive current, and the user watching the projector may be injured by the excessively strong laser.

therefore, how to protect the laser unit by other means is a focus of attention of those skilled in the art.

The background section is only provided to aid in understanding the present invention, and therefore the disclosure in the background section may include some known techniques which do not constitute a part of the knowledge of those skilled in the art. The disclosure in the "background" section does not represent that content or the problems which may be solved by one or more embodiments of the present invention are known or appreciated by those skilled in the art prior to the filing of the present application.

SUMMERY OF THE UTILITY MODEL

The utility model provides an electronic device can avoid providing too big electric current to the laser unit in the electronic device efficiently.

An embodiment of the present invention provides an electronic device. The electronic device comprises a laser unit, a laser power supply unit, a system control unit and a laser current monitoring unit. The system power supply unit is used for providing power for the electronic device. The system control unit is used for sending a first current control signal to the laser power supply unit. The laser power supply unit is used for providing current to the laser unit through the first current path according to the first current control signal, wherein the current flows back to the laser power supply unit from the laser unit through the second current path. In addition, the laser current monitoring unit is connected in series to the first current path and is used for continuously detecting the current value of the current. If the current value of the current is larger than the preset threshold value, the laser current monitoring unit is used for sending a second current control signal so as to reduce the current value of the current or stop the current from being supplied to the laser unit.

Based on the foregoing, the embodiment of the present invention provides an electronic device, which can monitor the current of the laser unit provided to the electronic device via the laser current monitoring unit that operates independently, so as to reduce or stop the current when the current is too large, and further avoid the damage of the laser unit of the electronic device due to the too large current.

In order to make the aforementioned and other features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

Drawings

Fig. 1 is a block diagram of an electronic device according to an embodiment of the present invention.

Fig. 2 is a block diagram of an electronic device according to another embodiment of the present invention.

fig. 3 is a flowchart illustrating a laser current protection method according to an embodiment of the present invention.

Fig. 4 is a flowchart illustrating a laser current protection method according to an embodiment of the present invention.

Fig. 5 is a block diagram of a laser current monitoring unit according to an embodiment of the present invention.

FIG. 6 is a block diagram of a projector according to the prior art.

Detailed Description

the foregoing and other features, aspects and utilities of the present invention will be apparent from the following more particular description of preferred embodiments of the invention, as illustrated in the accompanying drawings. Directional terms as referred to in the following examples, for example: up, down, left, right, front or rear, etc., are simply directions with reference to the drawings. Accordingly, the directional terminology is used for purposes of illustration and is in no way limiting.

Fig. 1 is a block diagram of an electronic device 10 according to an embodiment of the present invention.

referring to fig. 1, an electronic device 10 includes a system power supply unit 110, a system control unit 120, a laser power supply unit 130, a laser current monitoring unit 140, and a laser unit 150. The system control unit 120 is coupled (electrically connected) to the system power supply unit 110, the laser power supply unit 130, the laser current monitoring unit 140, and the laser unit 150. In this embodiment, the electronic device 10 may be, for example, a laser projector or other electronic device including a laser element, or may be an LED projector or other electronic device including a light emitting diode.

In the present embodiment, the system control unit 120 is hardware having arithmetic capability. The system control unit 120 is used for executing one or more program codes to manage the overall operation of the electronic device 10. In the present embodiment, the system control Unit 120 is, for example, a Central Processing Unit (CPU), a Programmable microprocessor (Micro-Processor), a Digital Signal Processor (DSP), a Programmable controller, an Application Specific Integrated Circuit (ASIC), a Programmable Logic Device (PLD), or the like. The system control unit 120 is configured to send a control signal to control the system power supply unit 110 and the laser power supply unit 130, so as to adjust the output current of the laser power supply unit 130, or to stop the output current of the system power supply unit 110 or the laser power supply unit 130. For example, in fig. 1, the control signal may be used to instruct the laser power supply unit 130 to generate the current C2, or may be used to instruct the system power supply unit 110 to stop outputting the current C1.

The system power supply unit 110 is used for managing power of the electronic device 10, i.e., the system power supply unit 110 is used for providing power to the electronic device 10. The system power supply unit 110 is also used for receiving power from the outside (e.g., commercial power, or other external power). The system power supply unit 110 may have an independent internal power source, such as a battery. In addition, the system power supply unit 110 is coupled to the laser power supply unit 130, and provides a voltage V1 (not shown) to the laser power supply unit 130 for supplying power, and the laser power supply unit 130 draws a required current C1 to the system power supply unit 110.

In the present embodiment, the laser power supply unit 130 is used to supply power to the laser unit 150. The system power supply unit 110 provides the electronic device with a system voltage to supply power, and the units in the electronic device draw required current to the system power supply unit 110 according to the requirement. Therefore, the laser power supply unit 130 receives the voltage V1 from the system power supply unit 110 and receives the current C1 from the system power supply unit 110, the system control unit 120 is configured to send the first current control signal SC1 to the laser power supply unit 130, the laser power supply unit 130 is configured to generate the current C2 according to the first current control signal SC1 received from the system control unit 120, and provide the current C2 to the laser unit 150 via the current path CP1 (also called, first current path). In another embodiment, the laser power supply unit 130 may be integrated into the system power supply unit 110, i.e., the system power supply unit 110 may generate the current C2 according to the first current control signal SC1 received from the system control unit 120.

in the present embodiment, the current C2 may flow back to the laser power supply unit 130 through the current path CP2 (also referred to as a second current path) after passing through the laser unit 150. In one embodiment, the laser power supply unit 130 may also receive a current feedback signal SB sent from the laser unit 150 to adjust the current value of the current C2 provided to the laser unit 150. In one embodiment, the laser power supply unit 130 may also receive the current feedback signal SB transmitted from the laser unit 150, and transmit information contained in the current feedback signal SB to the system control unit 120, where the information may be used to indicate that the current C2 is too large, and the system control unit 120 may transmit the third current control signal SC3 to the laser power supply unit 130 according to the information contained in the received current feedback signal SB, so that the laser power supply unit 130 adjusts the current value of the current C2 provided to the laser unit 150. Briefly, the laser power supply unit 130 is configured to receive an input current C1 and output a corresponding current C2 according to a received first current control signal SC 1.

in this embodiment, the electronic device 10 may be a projection device, which is used to receive image data (e.g., image data received from the data terminal or image data of a user interface generated by the system control unit 120) and project an image beam according to the image data to form a projection image on a projection plane. The projection device includes a light source module (including a laser unit 150), an optical engine, and a projection lens. The light source module can emit an illumination beam through at least the laser unit 150, the optical engine converts the illumination beam into an image beam based on the image data, and the projection lens projects the image beam onto a projection plane to form a projection image. The optical engine may include a light valve, such as, but not limited to, a Digital Micro-mirror Device (DMD), a Liquid Crystal On Silicon (LCOS), or a Liquid Crystal Display Panel (LCD Panel).

In the present embodiment, the laser current monitoring unit 140 is connected in series to the first current path CP 1. For example, the laser current monitoring unit 140 may be coupled to a node N1 (also referred to as a first node) on the first current path CP 1. The first node N1 may be disposed anywhere on the first current path CP 1. The laser current monitoring unit 140 is used for monitoring the current value of the current C2 flowing through the first node N1, and determining whether the current value of the current C2 needs to be reduced or the current C2 needs to be stopped according to the monitored current value of the current C2.

Fig. 2 is a block diagram of a laser current monitoring unit 140 according to an embodiment of the present invention. In the present embodiment, the laser current monitoring unit 140 includes a current detecting unit 141 and a current managing unit 142. The current detecting unit 141 is connected in series to the first current path CP1 to form a first node N1. The current detecting unit 141 may be configured to continuously detect a current value of the current C2 and transmit the detected current value of the current C2 to the current managing unit 142. The current detecting unit 141 may be any circuit structure or element capable of monitoring the magnitude of the current value in the current path, for example, the voltage across the resistor connected in series to the first current path CP1 is measured to estimate the magnitude of the current, or the current detecting unit is implemented by a Hall current sensor (Hall effect-based current sensor) or a channel Hall current sensor, which is not limited to the present invention. It should be noted that when the current sensing is implemented by means of a hall current sensor, the first node N1 does not have to be the node where the actual lines intersect.

Specifically, the current management unit 142 is coupled to the current detection unit 141. The current management unit 142 is configured to determine whether the current value of the current C2 is greater than a preset threshold according to the current value of the current C2 received from the current detection unit 141. The current management unit 142 is further configured to generate a second current control signal SC2 according to the determination result. The second current control signal SC2 is provided to the system control unit 120 to control the laser power supply unit 130 to decrease the current value of the current C2 or stop providing the current C2, or to control the system power supply unit 110 to stop providing the current C1. Please refer to fig. 1, fig. 3 and fig. 4 for details of the laser current monitoring unit and the laser unit protection method according to an embodiment of the present invention.

fig. 3 is a flowchart illustrating a laser current protection method according to an embodiment of the present invention. Referring to fig. 3, in step S31, the system control unit 120 sends a first current control signal SC1 to the laser power supply unit 130. Next, in step S32, the laser power supply unit 130 provides a current C2 to the laser unit 150 via a first current path CP1 according to the first current control signal SC 1.

In step S33, the laser current monitoring unit 140 continuously detects the current value of the current C2. Specifically, step S33 is continuously executed (e.g., every fixed predetermined period), so as to achieve the purpose of timely controlling the current value of the current C2 not to exceed the predetermined threshold.

In step S34, the laser current monitoring unit 140 determines whether the current value of the current C2 is greater than a preset threshold. Specifically, the preset threshold is set according to the specification of the laser unit 150 or the output brightness specification of the projection apparatus. That is, when the laser current monitoring unit 140 detects that the current value of the current C2 exceeds the preset threshold, the laser unit 150 may be damaged, or the projection apparatus (the laser unit 150) outputs an excessively bright image beam, so that the viewer may be visually injured by the excessively strong laser.

In response to determining that the current value of the current C2 is not greater than the preset threshold, the process returns to step S33; in response to determining that the current value of the current C2 is greater than the predetermined threshold, the laser current monitor unit 140 sends a second current control signal SC2 to the laser power supply unit 130 or the system control unit 120 to enable the laser power supply unit 130 to reduce the current value of the current C2 or stop the current from being supplied to the laser unit in step S35.

In one embodiment, the operation of step S35 may include one of the following embodiments (a1) and (a2) to stop providing the current C1 or the current C2.

Embodiment (a 1): the current management unit 142 may send the second current control signal SC2 to the laser power supply unit 130 or the system power supply unit 110 to instruct the laser power supply unit 130 or the system power supply unit 110 to stop supplying the current (e.g., the laser power supply unit 130 may stop supplying the current C2, or the system power supply unit 110 may stop supplying the current C1). That is, in the embodiment (a1), the second current control signal SC2 is used to instruct the circuit element receiving the second current control signal SC2 to stop providing the current to be transmitted.

Embodiment (a 2): the current management unit 142 sends a second current control signal SC2 to the system control unit 120. The second current control signal SC2 is used to indicate that the current value of the current C2 is greater than the preset threshold. The system control unit 120 sends a third current control signal SC3 to the laser power supply unit 130 or the system power supply unit 110 according to the received second current control signal SC2, so as to instruct the laser power supply unit 130 or the system power supply unit 110 to stop providing the current C1 or the current C2. That is, in the embodiment (a2), the third current control signal SC3 is used to instruct the circuit element receiving the third current control signal SC3 to stop providing the current to be transmitted.

On the other hand, the system power supply unit 110 may stop providing the current C1 by stopping the system power supply unit 110 from providing the voltage V1 of the system power supply unit 110 or changing the voltage V1 to the ground voltage (0V).

In an embodiment, the operation of the step S35 may include one of the following embodiments (B1) and (B2) to reduce the current value of the current C2.

Embodiment (B1): the current management unit 142 sends a second current control signal SC2 to the laser power supply unit 130 to instruct the laser power supply unit 130 to decrease the current value of the current (e.g., the laser power supply unit 130 may decrease the current value of the supplied current C2). That is, in the embodiment (B1), the second current control signal SC2 is used to instruct the circuit element receiving the second current control signal SC2 to decrease the current value of the current originally supplied.

Embodiment (B2): the current managing unit 142 sends a second current control signal SC2 to the system control unit 120, wherein the second current control signal SC2 is used to indicate that the current value of the current is larger than a preset threshold. The system control unit 120 sends a third current control signal SC3 to the laser power supply unit 130 according to the received second current control signal SC2, so as to instruct the laser power supply unit 130 to decrease the current value of the current C2. That is, in the embodiment (B2), the third current control signal SC3 is used to instruct the circuit element receiving the third current control signal SC3 to reduce the supply of the current to be transmitted.

The circuit elements of embodiments (a1), (a2), (B1) and (B2) receiving the second/third current control signal SC2/SC3 may be any devices and circuits that are actuated to influence the supply of the current C1 or the current C2, for example, the circuit elements may be connected in series to a path of the laser power supply unit 130 receiving the voltage V1 from the system power supply unit 110 to turn off the laser power supply unit 130; or a switch for shunting current C2, may temporarily reduce the actual current flowing into laser unit 150.

In addition, in order to avoid that the current C2 cannot be effectively reduced, in the embodiments corresponding to the embodiments (B1) and (B2), the supplied current C2 may also be directly stopped according to the reduction count value corresponding to the transmitted second current control signal SC 2. This is explained in detail below with reference to fig. 4.

Fig. 4 is a flowchart illustrating a laser current protection method according to an embodiment of the present invention. Referring to FIG. 4, steps S31-S34 are the same as steps S31-S34 in FIG. 3, and are not described herein again.

In response to the determination that the current value of the current C2 is greater than the predetermined threshold (step S34 → yes), the laser current monitoring unit 140 (the current management unit 142) determines whether the current reduction count value is greater than the reduction count threshold in step S351. Specifically, the initial value of the reduction count value is zero, and the current management unit 142 accumulates the reduction count value (e.g., adds one) each time the current management unit 142 sends the second current control signal SC 2. That is, according to the value of the reduction number value, the current management unit 142 may know the total number of times the current management unit 142 has transmitted the second current control signal SC2 before the time point at which the current value of the current C2 is determined to be greater than the preset threshold value this time. The designer or manufacturer may set the reduction number threshold according to the requirement.

In response to determining that the reduction count value of the current is not greater than the reduction count threshold (step S351 → no), continuing to step S352, the current management unit 142 sends the second current control signal SC2 to reduce the current value of the current C2, and accumulates the reduction count value. Details of step 352 have already been described in the above embodiments (B1) and (B2) of step S35, and are not described herein again.

Then, the flow returns to step S33. That is, the laser current monitor unit 140 may continue to detect the current value of the current C2 to determine whether the current value of the current C2 is greater than the preset threshold again, and may further recognize whether the transmitted second current control signal SC2 is active (i.e., determine whether the current value of the current C2 is reduced via the transmitted second current control signal SC 2).

In response to determining that the decreasing number of times of the current is greater than the decreasing number threshold (step S351 → yes), continuing to step S353, the current management unit 142 sends a fourth current control signal SC4, wherein the fourth current control signal SC4 is used for indicating to stop providing the current C1 or the current C2. Specifically, the fourth current control signal SC4 may be sent to the laser power supply unit 130 or the system power supply unit 110 to instruct the laser power supply unit 130 or the system power supply unit 110 to stop supplying current (e.g., the laser power supply unit 130 may stop supplying current C2, and the system power supply unit 110 may stop supplying current C1). In one embodiment, the current management unit 142 sends the fourth current control signal SC4 to the system control unit 120, and the system control unit 120 can send a command to stop the current supply to the laser power supply unit 130 or the system power supply unit 110, so that the laser power supply unit 130 stops supplying the current C2 or the system power supply unit 110 stops supplying the current C1 or the voltage V1. The fourth current control signal SC4 is similar to the second current control signal SC2 in the above embodiments (a1) and (a2), and the details thereof are not repeated here.

on the other hand, in step S354, in response to determining that the current value of the current C2 is not greater than the preset threshold (step S34 → no), the current management unit 142 resets the reduction number value to zero. That is, when the current management unit 142 determines that the current value of the current C2 is not greater than the predetermined threshold, the decrement count value is reset to zero to avoid continuing to accumulate the decrement count value, and thus the decrement count value is prevented from being accumulated until the decrement count value exceeds the decrement count threshold, which leads to an unexpected operation in step S353. After resetting the number of times of decrease to zero, the flow returns to step S33.

Fig. 5 is a block diagram of an electronic device according to another embodiment of the present invention. Referring to fig. 5, different from fig. 1, the electronic device 10 of fig. 5 further includes a current cut-off unit 160. In this another embodiment, the current cut-off unit 160 is disposed on the second node N2 in the first current path CP 1. A second node N2 is located between the first node N1 and the laser unit 150.

The current cut-off unit 160 may disconnect the first current path CP1 according to a current value of the current C2 greater than a predetermined value (also referred to as a cut-off threshold).

Specifically, in response to the current management unit 160 monitoring that the current value of the current is greater than the cutoff threshold, the current cutoff unit 160 opens the first current path CP1 to stop the current from being supplied to the laser unit 150. The cutoff threshold is greater than the preset threshold. The current cut-off unit 160 is a circuit element such as a fuse or a thermistor (PCT), and is disposed on the first current path (which is a part of the first current path) to allow the current C2 to pass through. However, when the value of the passing current C2 is greater than the cut-off threshold, the current cut-off unit 160 will blow to disconnect the first current path, thereby preventing the current C2 from flowing to the laser unit 150.

To sum up, the embodiment of the present invention provides an electronic device and a method for protecting a laser unit thereof, which can monitor the current of the laser unit provided to the electronic device via a laser current monitoring unit that operates independently, so as to reduce or stop the current when the current is too large, thereby avoiding the damage of the laser unit of the electronic device due to the too large current.

Although the present invention has been described with reference to the above embodiments, it is not intended to limit the present invention, and those skilled in the art can make various changes and modifications without departing from the spirit and scope of the present invention, so that the scope of the present invention is to be defined by the appended claims.

Description of reference numerals:

10: electronic device

110: system power supply unit

120: system control unit

130: laser power supply unit

140: laser current monitoring unit

141: current detection unit

142: current management unit

150: laser unit

160: current cutoff unit

N1, N2: node point

C1, C2: electric current

CP1, CP 2: current path

SB: current feedback signal

SC, SC1, SC2, SC3, SC 4: current control signal

s31, S32, S33, S34, S35: process steps of laser unit protection method

S31, S32, S33, S34, S351, S352, S353, S354: the flow steps of the laser unit protection method.

Claims (7)

1. An electronic device, comprising a system power supply unit, a system control unit, a laser power supply unit, a laser unit, and a laser current monitoring unit, wherein:

the system power supply unit is used for providing the electronic device power;

The system control unit is used for sending a first current control signal to the laser power supply unit;

The laser power supply unit is used for providing current to the laser unit through a first current path according to the first current control signal, wherein the current flows back to the laser power supply unit from the laser unit through a second current path; and

The laser current monitoring unit is connected in series with the first current path,

The laser current monitoring unit is used for continuously detecting the current value of the current,

Wherein if the current value of the current is greater than a preset threshold, the laser current monitoring unit is configured to send a second current control signal to reduce the current value of the current or stop the current from being provided to the laser unit.

2. The electronic device of claim 1, wherein the laser current monitoring unit comprises a current detection unit and a current management unit, wherein:

The current detection unit is connected in series on a first current path to form a first node, and the current detection unit is used for continuously detecting the current value of the current; and

The current management unit is coupled to the current detection unit, wherein the current management unit is configured to determine whether the current value of the current is greater than the preset threshold,

Wherein the current management unit is further configured to generate the second current control signal.

3. the electronic device according to claim 2, wherein the laser current monitoring unit is configured to send the second current control signal to reduce the current value of the current or stop the current from being supplied to the laser unit,

The current management unit sends the second current control signal to the laser power supply unit or the system power supply unit to instruct the laser power supply unit or the system power supply unit to stop providing the current; or

The current management unit sends the second current control signal to the system control unit, wherein the second current control signal is used for indicating that the current value of the current is greater than the preset threshold value, and the system control unit sends a third current control signal to the laser power supply unit or the system power supply unit according to the received second current control signal so as to indicate that the laser power supply unit or the system power supply unit stops providing the current.

4. The electronic device according to claim 2, wherein the laser current monitoring unit is configured to send the second current control signal to reduce the current value of the current or stop the current from being supplied to the laser unit,

the current management unit sends the second current control signal to the laser power supply unit to instruct the laser power supply unit to reduce the current value of the current; or

The current management unit sends the second current control signal to the system control unit, wherein the second current control signal is used for indicating that the current value of the current is greater than the preset threshold value, and the system control unit sends a third current control signal to the laser power supply unit according to the received second current control signal so as to indicate the laser power supply unit to reduce the current value of the current.

5. the electronic device of claim 4,

Each time the current management unit sends the second current control signal, the current management unit accumulates a reduction count value,

Wherein after the current management unit sends the second current control signal, the current management unit performs the above-mentioned step of determining whether the current value of the current is greater than the preset threshold value again,

Wherein when the reduction number value is greater than a reduction number threshold and it is determined that the current value of the current is greater than the preset threshold, the current management unit transmits a fourth current control signal to one of the laser power supply unit or the system power supply unit, and

Wherein the fourth current control signal is used to indicate that the current stops being provided.

6. The electronic device of claim 5,

When the current management unit determines that the current value of the current is not greater than the preset threshold value, the current management unit resets the reduction number value to zero.

7. the electronic device according to claim 2, further comprising a current cut-off unit,

Wherein the current cut-off unit is connected in series on the first current path to form a second node, wherein the second node is located between the first node and the laser unit,

Wherein the current cutoff unit opens the first current path to stop the current from being provided to the laser unit in response to the current management unit monitoring that the current value of the current is greater than a cutoff threshold, wherein the cutoff threshold is greater than the preset threshold.