A micro-electro-mechanical system (MEMS) switch 100, an example of which is shown in
Since the electrostatic force is dependent on the gate-to-beam delta voltage (Vgate-Vbeam), MEMS switches are sensitive to any effective alteration of the voltage between the gate 112 and beam 102 of the switch 100. An alternating current (AC) signal with a large amplitude, for example an RF signal, can alter the Vgate-Vbeam delta voltage, such that an unintended result may occur. Under such conditions, the switch 100 may be initially on, and de-actuate unintentionally. Similarly, the switch 100 may be initially off, and actuate unintentionally. Both unintended events are a result of the signal propagating through the switch 100, causing a change in the electrostatic force to be either less than the mechanical restoring force of a beam in the closed state or greater that the beam mechanical restoring force in the open state. Unintentionally changing the state of the switch while a signal is being actively conducted by the switch is referred to as “hot switching.” Hot switching, especially if it occurs often, may have a significant effect on the life and reliability of the switch due to contact erosion and heating of the switch.
A voltage source 134 generates a raw actuation signal 136 with a voltage sufficient to actuate the switch 120. A switch controller 138 provides an actuating signal 140 to the driver 126, which selectively couples the raw actuation signal 136 to the gate 130 of the switch 120 as the actuation signal 128. When the switch controller 138 causes raw actuation signal 136 to be coupled to the switch gate 130 through the driver, the switch is actuated to its closed (i.e., on) state.
The described embodiments may comprise a switch self-actuation mitigation system based on a generated tracking signal. The system may utilize a high-impedance and low parasitic coupling configuration of the RF input signal to generate a corrective tracking signal. The tracking signal may be applied to the switch gate, in-phase with the signal on the switch beam, to reduce or eliminate the variation on the Vgate-Vbeam delta voltage that causes undesired excursions below the pull-out voltage VPO of the switch in its closed state, or excursions above the pull-in voltage of the switch in its open state.
In one aspect, the invention may be an apparatus for mitigating self-actuation of a switch, comprising an input port of the switch configured to receive a radio frequency input signal, an actuator configured to selectively apply an actuating voltage to the switch, thereby causing a state of the switch to change from one of non-conductive to conductive or conductive to non-conductive, a coupler configured to couple at least a portion of the input signal to the actuating voltage, and an output port that is electrically coupled to the input port when the state of the switch is conductive. The switch may further comprise an output port, a mechanically movable element (e.g., a beam) configured to selectively couple the input port to the output port, and a gate configured to facilitate application of the actuating force to the mechanically movable element.
The coupler may comprise a capacitor having a first terminal and a second terminal, the first terminal electrically coupled to the input port and the second terminal electrically coupled to the gate. The radio frequency input signal may be characterized by a minimum frequency that is larger than a resonant frequency of the mechanically movable element.
The actuator may be configured to apply the actuating voltage to the switch through a resistor. A first terminal of the resistor may be electrically coupled to the actuator, and a second terminal of the resistor may be electrically coupled to a node. The node may be further electrically coupled to the gate, such that the coupler conveys at least a portion of the input signal to the node
The actuator may comprise an actuating voltage source, a driver, a switch controller, a first resistor and a second resistor. The actuating voltage source may be electrically coupled to a node through the first resistor, a first port of the driver may be coupled to the node, and a second port of the driver may be electrically coupled to a reference potential (e.g., ground). A control port of the driver may be electrically coupled to the switch controller, and the node may be electrically coupled to the gate through the second resistor. The driver may selectively couple the first port of the driver to the second port of the driver in response to a switch control signal from the switch controller, which is applied to the control port of the driver.
The mechanically movable element may comprise two or more movable segments, each of which is configured to selectively couple the input port to a respective output port.
The switch may comprise a first switch segment comprising a first output port, a first mechanically movable element configured to selectively electrically couple the first input port to the first output port, and a first gate configured to facilitate application of the actuating force to the first mechanically movable element. The switch may further comprise a second switch segment comprising a second output port, a second mechanically movable element configured to selectively electrically couple the second input port to the second output port, and a second gate configured to facilitate application of the actuating force to the second mechanically movable element. The first gate may be electrically coupled to the second gate, the first output port may be electrically coupled to the second input port.
The coupler may comprise a capacitor having a first terminal and a second terminal. The first terminal may be electrically coupled to the first output port and the second input port, and the second terminal may be electrically coupled to the first gate and the second gate.
The actuator may comprise an actuating voltage source, a driver, a switch controller, a first resistor and a second resistor. The actuating voltage source may be electrically coupled to a node through the first resistor, a first port of the driver may be electrically coupled to the node through a second resistor, the first port of the driver may be coupled to the gate, and the coupler may couple the input signal to the node. A control port of the driver may be electrically coupled to the switch controller, and the driver may selectively couple the first port of the driver to the second port of the driver in response to a switch control signal from the switch controller applied to the control port of the driver. The coupler may further comprise a filter, which may be a low pass filter. In other embodiments, the filter may be a band pass filter.
In another aspect, the invention may be a method of mitigating self-actuation of a switch. The method may comprise coupling an input signal from a signal source to an input port of the switch, and combining at least a portion of the input signal with a switch actuating voltage, thereby forming a tracking signal configured to facilitate a switch actuation force.
The switch may further comprise (i) a mechanically movable element (i.e., a beam) configured to selectively couple the input port of the switch to an output port of the switch, and (ii) a gate configured to apply an actuating force to the mechanically movable element. Combining at least a portion of the input signal with the switch actuating voltage may further comprise at least partially coupling the input signal to the gate. At least partially coupling the input signal to the gate may further comprise disposing a capacitor between the input port of the switch and the gate. The method may further comprise applying, by an actuator, an actuating voltage to the gate. Applying an actuating voltage to the gate may further comprise selectively coupling a node to a reference potential in response to a switch control signal. The node may be electrically coupled to the gate through a first resistor, and be electrically coupled to an actuating voltage source through a second resistor.
The patent or application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawings will be provided by the Office upon request and payment of the necessary fee.
The foregoing will be apparent from the following more particular description of example embodiments, as illustrated in the accompanying drawings in which like reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating embodiments.
A description of example embodiments follows.
The voltage controller 208 comprises a voltage source 212, a driver 214, a switch controller 216, a resistor 218, a second resistor 218a, and a capacitor 220. The voltage source 212 generates a raw actuation signal 222 with a voltage sufficient to actuate the switch 202. The raw actuation voltage signal 222 is coupled to a first port the second resistor 218a. The second port of the second resistor 218a is coupled to a node 221 that couples a first port of the resistor 218 to a driver port 224. The second port of the resistor 218 is coupled to the gate 226 of the switch 202 and to a first port of the capacitor 220. The second port of the capacitor 220 is coupled to the connection between the signal source 204 and the switch 202, which conveys the signal 205.
The switch controller 216 provides a switch control signal 228 to a control input 230 of the driver. The switch control signal 228 causes the driver 214 to selectively couple the port 224 of the driver to port 232 of the driver. The port 232 of the driver is connected to a reference potential (e.g., ground potential). The switch control signal therefore selectively connects and disconnects node 221 to ground.
When the driver connects node 221 to ground, the gate 226 of the switch is effectively tied to ground. When the driver disconnects node 221 from ground, the gate 226 of the switch is effectively at the voltage of the raw actuation voltage signal 222, plus the signal 205 coupled by the capacitor 220. In the example embodiment, the resistors 218 and 218a each have a value of 100K ohms, and the capacitor 220 has a value of 0.01 μF, although these values are only examples and are not intended to be limiting.
The capacitor 220 couples the signal 205 to the actuation signal 226, so that the signal 205 is AC coupled, in-phase, to the actuation signal 210, thereby combining AC components of the output of the signal source with the raw actuation signal 222 and forming a tracking signal. The capacitor 220 further prevents the direct current (DC) actuation voltage from affecting the signal 205.
Certain applications using a MEMS switch may require a switch with a single input and two or more outputs. The described embodiments may be used to mitigate self-actuation of a switch having such multiple outputs.
It should be noted that as the frequency of the input signal increases, even large excursions across the VPO threshold may not cause a de-actuation event. This is because at higher frequencies, the excursion may be shorter than the beam's mechanical response time. In other words, before the beam exhibits a substantial mechanical response, the signal voltage reverses back toward the “safe” actuated side of the VPO threshold.
In this example, the excursion of the higher frequency signal 502 below the VPO threshold is small enough that the integrated voltage is less than the switch OFF integrated voltage threshold, so the likelihood of de-actuation is relatively small. The lower frequency signal 504 excursion is large enough that the integrated voltage below VPO is greater than the switch OFF integrated voltage threshold, so in this case the likelihood of de-activation is relatively large. As the amplitude of the signals increases, even the higher frequency signal excursion below the VPO threshold will be large enough to exceed the switch OFF integrated voltage threshold. Further, in the region 506c, the integrated voltage above VPI is greater than the on integrated voltage threshold, so the switch may re-actuate, thereby causing a hot switch event.
In some embodiments of the tracking signal-based switch self-actuation mitigation system, components for coupling the input AC signal to the actuation signal may be on a circuit board or other module separate from the switch and driver. In other embodiments, the coupling components may be arranged on a substrate die within a multi-chip module that also houses the switch and driver. In other embodiments, two or more of the coupling components, the switch and the driver may be integrated on a single substrate.
Certain applications using a MEMS switch may require a pair of switches, connected in series, driven by a common gate. For such a configuration, the coupling point between the two switches should be considered when generating the tracking signal.
While the example embodiments of a switch self-actuation mitigation system based on a generated tracking signal are described with respect to a MEMS switch, it should be understood that the embodiments may alternatively be applied to other types of switch technologies, for example RF silicon on insulator (SOI), GaN, and GaAs, among others.
While example embodiments have been particularly shown and described, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the embodiments encompassed by the appended claims.
This application claims the benefit of U.S. Provisional Application No. 62/691,232, filed on Jun. 28, 2018. The entire teachings of the above application are incorporated herein by reference.
Number | Date | Country | |
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62691232 | Jun 2018 | US |