VOLTAGE BAND-PASS ENABLE CIRCUIT
An enable circuit includes a first detection controller, a second detection controller, and an enable switch. The first detection controller has a first input terminal coupled to a first input terminal voltage and a first output terminal. The second detection controller has a second input terminal coupled to the first input terminal voltage and a second output terminal. The enable switch has a control terminal coupled to the second output terminal, a third input terminal coupled to a second input terminal voltage, and a third output terminal. When the first input terminal voltage is higher than the first setting voltage but lower than the second setting voltage, the enable circuit is coupled to ground by the second output terminal, thus the enable switch is turned on to output an enable signal from the third output terminal, wherein the enable signal is provided by a second input terminal voltage.
This application claims priority to and the benefit of Taiwan Application No. 107115038, filed May 3, 2018.
Field of the InventionThe invention relates to an enable circuit, especially relating to a voltage band-pass enable circuit. When the enable circuit detects an input voltage that falls into a specific range of voltage, the enable circuit can output an enable signal to the circuit or device to be enabled.
Description of the Related ArtElectronic devices (or components) on the market all have power input pins and enable pins, and most of these electronic devices cannot be enabled until they receive stable power or power that approaches a specific voltage level. Unstable power or power that doesn't approach a specific voltage level may lead to abnormal actions on the part of the electronic devices, or even damage the electronic devices.
Some specific power conversion circuits are applied. For example, a boost converter in a system can boost an input voltage ranging from 5V to 20V to an output voltage ranging from 5V to 12V. However, the input voltage is always lower than the output voltage for the boost converter. In other words, when the input voltage of the boost converter is higher than 12V, the boost converter of the system can be disabled first, and the input voltage of the boost converter can be directly applied to a load (an electronic device or another system) connected to the system, thereby improving power conversion efficiency and the power stability of the system.
BRIEF SUMMARY OF THE INVENTIONIn order to resolve the issue described above, the invention provides an enable circuit that enables a post circuit only when an input voltage is higher than an enable threshold voltage and disables the post circuit only when the input voltage is higher than a disable threshold voltage. A first setting voltage (enable threshold voltage) and a second setting voltage (disable threshold voltage) that are both adjustable are provided in the invention to send out an enable or disable signal to the post circuit.
In more detail, an embodiment of the invention provides an enable circuit that comprises a first detection controller, a second detection controller, and an enable switch. The first detection controller has a first input terminal coupled to a first input terminal voltage and a first output terminal, wherein when the first input terminal voltage is not higher than the first setting voltage, the first detection controller connects the first output terminal to a ground; when the first input terminal voltage is higher than the first setting voltage, the first detection controller disconnects the first output terminal from the ground. The second detection controller has a second input terminal coupled to the first input terminal voltage and a second output terminal, wherein the second input terminal is further coupled to the first output terminal, and when the first input terminal voltage is not higher than the second setting voltage, the second detection controller connects the second output terminal to the ground; when the first input terminal voltage is higher than the second setting voltage, the second detection controller disconnects the second output terminal from the ground. The second setting voltage is higher than the first setting voltage. The enable switch has a control terminal coupled to the second output terminal, a third input terminal coupled to a second input terminal voltage, and a third output terminal, wherein when the first input terminal voltage is higher than the first setting voltage but lower than the second setting voltage, the enable circuit is coupled to the ground by the second output terminal, so that the enable switch is turned on to output an enable signal from the third output terminal, wherein the enable signal is provided by the second input terminal voltage.
According to the enable circuit disclosed above, the first input terminal voltage is provided by a first input terminal power. After the first input terminal power starts up, when the first input terminal voltage is increased from the first setting voltage to the second setting voltage, the enable circuit outputs the enable signal.
According to the enable circuit disclosed above, further comprising one or more voltage clamping devices coupled to the first input terminal of the first detection controller, the second input terminal of the second detection controller, or between the third input terminal of the enable switch and the ground, to clamp the first input terminal voltage or the second input terminal voltage under the rating voltage of the first detection controller or the second detection controller.
An embodiment of the invention provides a power switching system, comprising the enable circuit disclosed in claim 1, a two-way switch, and a DC-DC boost converter. The enable circuit disclosed in claim 1 receives the first input terminal voltage, and when the first input terminal voltage is higher than the first setting voltage but lower than the second setting voltage, the enable circuit outputs the enable signal from the third output terminal. The two-way switch has an input, an output control terminal, a fourth output terminal, and a fifth output terminal. The input receives the first input terminal voltage, and the output control terminal couples to the third output terminal of the enable circuit. The two-way switch connects the input to the fourth output terminal when receiving the enable signal, but otherwise connects the input to the fifth output terminal. The DC-DC boost converter couples to the fourth output terminal of the two-way switch, and boosts the first input terminal voltage from the fourth input terminal when receiving the enable signal.
The invention can be more fully understood by reading the subsequent detailed description with references made to the accompanying figures. It should be understood that the figures are not drawn to scale in accordance with standard practice in the industry. In fact, it is allowed to arbitrarily enlarge or reduce the size of components for clear illustration.
The first detection controller 102 detects the first input terminal voltage (VA) via the voltage divided resistors R1 and R2. The first detection controller 102 configured to connect the first output terminal OUT1 to a ground when the first input terminal voltage (VA) is not higher than the first setting voltage (VL), and to disconnect the first output terminal OUT1 from the ground when the first input terminal voltage (VA) is higher than the first setting voltage (VL). The second detection controller 104 detects the second input terminal voltage (VA) via the voltage divided resistors R3 and R4. The second detection controller 104 connects the second output terminal OUT2 to the ground when the first input terminal voltage (VA) is not higher than the second setting voltage (VH), and to disconnect the second output terminal OUT2 from the ground when the first input terminal voltage (VA) is higher than the second setting voltage (VH). It should be noted that the second setting voltage (VH) is higher than the first setting voltage (VL). The second output terminal OUT2 of the enable circuit 100 is connected to the ground, second input terminal, third output terminal when the first input terminal voltage (VA) is higher than the first setting voltage (VL) but lower than the second setting voltage (VH), and thereby the enable switch 106 is turned on to output an enable signal powered by the second input terminal voltage (VB) to the third output terminal OUT3.
The second detection controller 104 has the same internal structure as the first detection controller 102. As shown in
The enable switch 106 has a control terminal TC coupled to the second output terminal OUT2 of the second detection controller 104, a third input terminal IN3 coupled to a second input terminal voltage (VB), and a third output terminal OUT3. Here, for example, the enable switch 106 is a PMOS transistor with a gate as the control terminal TC, a source as the third input terminal IN3, and a drain as the third output terminal OUT3. When the first input terminal voltage (VA) is higher than the first setting voltage (VL) (that is, the voltage V1 is higher than the first reference voltage (Vref1)), the first detection controller 102 disconnects the first output terminal OUT1 from the ground, and thus the voltage V2 on the first output terminal OUT1 is the voltage that is divided by the voltage divided resistors R3 and R4 from the first input terminal voltage (VA). When the first input terminal voltage (VA) is not higher than the second setting voltage (VH) (that is, the voltage V2 is not higher than the second reference voltage (Vref2)), the second detection controller 104 connects the second output terminal OUT2 to the ground. At this time, due to the second output terminal OUT2 having a voltage of 0V(grounded), the voltage across resistor R6 can bias the gate and the source of the PMOS by negative voltage (−V3), so that the PMOS is turned on, and thus the third output terminal OUT3 can output the voltage V3 of the third input terminal IN3 as the enable signal to post circuits or devices. The voltage V3 is the voltage that is divided by the voltage divided resistors R5 and R6 from the second input terminal voltage (VB).
When the first input terminal voltage (VA) is higher than the second setting voltage (VH) (that is, the voltage V2 is higher than the second reference voltage (Vref2)), the second detection controller 104 disconnects the second output terminal OUT2 from the ground, and the voltage across resistor R6 cannot bias the gate and the source of the PMOS transistor, so that the PMOS transistor is turned off, and thus the third output terminal OUT3 cannot output the voltage V3 of the third input terminal IN3 as the enable signal.
V1=VA*R2/(R1+R2)
V2=VA*R4/(R3+R4)
When the second detection controller 104 connects the second output terminal OUT2 to the ground, the relationship between the voltage V3 and the voltage divided resistors (R5−R6) is as follows,
V3=VB*R6/(R5+R6)
The relationship between the first setting voltage (VL) of the first detection controller 102, the second setting voltage (VH) of the second detection controller 104, the first reference voltage Vref1, and the second reference voltage Vref2 is as follows:
VL=Vref1*(1+R1/R2)
VH=Vref2*(1+R3/R4)
Therefore, by adjusting or setting the first and second reference voltage (Vref1 and Vref2) in the first detection controller 102 and the second detection controller 104, and/or adjusting or setting the resistance of the voltage divided resistors (R1−R4), the first setting voltage (VL) and the second setting voltage (VH) can be set. Thus, the enable circuit 100 disclosed in the present invention can output the enable signal when the first input terminal voltage (VA) is higher than the first setting voltage (VL) but lower than the second setting voltage (VH). Thus, the enable circuit 100 disclosed in the present invention is a voltage band-pass enable circuit: That is, the enable signal is output only when the first input terminal voltage (VA) is higher than the first setting voltage (VL) but lower than the second setting voltage (VH).
As shown in
Zener diodes (D1-D3) in
DC-DC boost converter 504 has a fifth input terminal INS that connects to the fourth output terminal OUT4 of the two-way switch 502, and a second control terminal TC2 that receives the enable signal. When the enable signal is at logic high level, the DC-DC boost converter 504 is enabled to boost the first input terminal voltage (VA) to a specific voltage (VD) via the two-way switch 502, wherein the specific voltage (VD) is higher than the first input terminal voltage (VA). When the enable signal is at logic low level, the DC-DC boost converter 504 is then disabled.
The enable circuit disclosed in the present invention can be applied on electronic devices with multiple inputs from different power sources. For example, a removable display laptop includes a base board and a removable display. In general, the operation voltage of the base board is 5V, but the operation voltage of the removable display is 12V. Thus a DC-DC boost converter (such as element 504 in
The ordinal in the specification and the claims of the present invention, such as “first”, “second”, “third”, etc., has no sequential relationship, and is just for distinguishing between two different components with the same name. In the specification of the present invention, the word “couple” refers to any kind of direct or indirect electronic connection. The present invention is disclosed in the preferred embodiments as described above, however, the breadth and scope of the present invention should not be limited by any of the embodiments described above. Persons skilled in the art can make small changes and retouches without departing from the spirit and scope of the invention. The scope of the invention should be defined in accordance with the following claims and their equivalents.
Claims
1. An enable circuit, comprising:
- a first detection controller, with a first input terminal coupled to a first input terminal voltage and a first output terminal, wherein when the first input terminal voltage is not higher than a first setting voltage, the first detection controller connects the first output terminal to a ground; when the first input terminal voltage is higher than the first setting voltage, the first detection controller disconnects the first output terminal from the ground;
- a second detection controller, with a second input terminal coupled to the first input terminal voltage and a second output terminal, wherein the second input terminal is further coupled to the first output terminal, and when the first input terminal voltage is not higher than a second setting voltage, the second detection controller connects the second output terminal to the ground; when the first input terminal voltage is higher than the second setting voltage, the second detection controller disconnects the second output terminal from the ground; wherein the second setting voltage is higher than the first setting voltage; and
- an enable switch, with a control terminal coupled to the second output terminal, a third input terminal coupled to a second input terminal voltage, and a third output terminal;
- wherein when the first input terminal voltage is higher than the first setting voltage but lower than the second setting voltage, the enable circuit is coupled to the ground by the second output terminal, so that the enable switch is turned on to output from the third output terminal an enable
2. The enable circuit as claimed in claim 1, wherein the first input terminal voltage is provided by a first input terminal power; after the first input terminal power starts up, when the first input terminal voltage is increased from the first setting voltage to the second setting voltage, the enable circuit outputs the enable signal.
3. The enable circuit as claimed in claim 1, further comprising one or more voltage clamping devices, coupled to the first input terminal of the first detection controller, the second input terminal of the second detection controller, or between the third input terminal of the enable switch and the ground, to clamp the first input terminal voltage or the second input terminal voltage under a rating voltage of the first detection controller or the second detection controller.
4. A power switching system, comprising:
- the enable circuit of claim 1, receiving the first input terminal voltage, and when the first input terminal voltage is higher than the first setting voltage but lower than the second setting voltage, outputting the enable signal from the third output terminal;
- a two-way switch, with an input terminal, an output control terminal, a fourth output terminal, and a fifth output terminal; wherein the input terminal receives the first input terminal voltage, and the output control terminal couples to the third output terminal of the enable circuit; the two-way switch connects the input terminal to the fourth output terminal when receiving the enable signal, but otherwise connects the input to the fifth output terminal;
- a DC-DC boost converter, couples to the fourth output terminal of the two-way switch, and boosts the first input terminal voltage output from the fourth input terminal when receiving the enable signal.
Type: Application
Filed: Aug 20, 2018
Publication Date: Nov 7, 2019
Inventor: Hsin-Chih KUO (Taoyuan City)
Application Number: 16/105,198