The present disclosure relates electro-mechanical relays, particularly to electro-mechanical relays that can operate as Micro-Electro-Mechanical Systems (MEMS) technology as well as nanotechnology.
Electro-mechanical relays were historically discrete analog switches that were used in early computers for such applications as to implement Boolean logic. Discrete electro-mechanical relays continue in common usage for certain commercial, automotive, communications, automation, power, and other applications. Inherent advantages of electro-mechanical relays include relatively low current leakage and excellent reliability of operation.
Transistors have largely supplanted electro-mechanical relays in such applications as computers, digital logic, and communications. Fabrication of transistors, and other such devices, relies on such solid-state semiconductor processing techniques. Conventional transistors (including, for example, NMOS, CMOS, field effect transistors, bipolar transistors, or other types) have some voltage drop across their terminals that typically result in current leakage. Such leakage can result in considerable power consumption for the transistors themselves as well as their associated circuits. Additionally, transistors have difficulty operating in harsh or radioactive environments.
Therefore, there is a need in the art for switching devices having limited current leakage, as well as being able to function in harsh or radioactive environments.
Embodiments of the present invention include a nano/micro electro-mechanical relay, comprising an at least one normally open (NO) nano/micro relay switch and an at least one normally closed (NC) nano/micro relay switch. Both the NC nano/micro relay switch and the NO nano/micro relay switch operationally include at least one displaceable contact pad that can be displaced relative to at least one substrate anchored pad to substantially simultaneously switch the NC nano/micro relay switch and the NO nano/micro relay switch between their respective normal relay switch positions and their respective actuated relay switch positions. An at least one nano/micro actuator including an at least one piezoelectric stack layer being attached to an at least one elastic layer, wherein to actuate the at least one nano/micro actuator, the at least one piezoelectric stack layer contracts to deflect the at least one elastic layer. Certain embodiments of the nano/micro electro-mechanical relay can further include at least one nano/micro contact bar that when actuated by the at least one nano/micro actuator configured to simultaneously switch the NC nano/micro relay switch and the NO nano/micro relay switch between their respective normal relay switch position and their respective actuated relay switch positions. The simultaneous switching can be at least partially in response to deflection of the at least one nano/micro actuator.
Throughout this disclosure, similar reference characters may be provided for similar elements in the different embodiments, which may perform identical or similar functions. For example, there are multiple conductive traces attached to each of the normally open (NO) relay switch and normally closed (NC) relay switch in each of the different embodiments of the relay switches illustrated in different ones of the figures. As such, each conductive trace may be provided the same reference number, though a reference letters can be appended where necessary such as 84, 84a, 84b, 84c, 84d, etc. Within this disclosure, any description referring to one device having the reference character can refer, depending on context, to other devices sharing that reference character.
A nano/micro electro-mechanical relay 60 provides some of the design functionality that can be used to provide a variety of nano/micro electro-mechanical digital relay circuits, some of which are described later in the disclosure. Certain embodiments of the nano/micro relay switch pairs 64 comprise at least one NO (normally open) nano/micro relay switch 80, at least one NC (normally closed) nano/micro relay switch 82 and a nano/micro actuator 70. As known with switch terminology, each NO nano/micro relay switch 80 and NC nano/micro relay switch 82 can be configured to be switched between the closed (e.g., on) position and the open (e.g., off) position. The normal position for each NO nano/micro relay switch 80 or NC nano/micro relay switch 82, representing the position without actuation while the actuated position represents the respective position during actuation. As such, NO nano/micro relay switches would normally be open, but upon actuation are closed. By comparison, NC nano/micro relay switches are normally be closed, but open upon actuation.
One advantage of bringing the nano/micro electro-mechanical relay 60 to the nanoscale as well as to ULSI (ultra-large scale integration), or even lower levels, is that such structures can be fabricated using techniques presently being applied for transistor-based devices, such as complementary metal oxide semiconductor (CMOS). Many transistor-based switching devices rely on biasing the different terminals of the transistor to alter the electric current passing through the transistor. By comparison, certain embodiments of the nano/micro electro-mechanical relay can provide switching functionality based on an electrically controlled mechanical displacement of at least part of the nano/micro relay switch pair 64 resulting largely by actuating the nano/micro relay switch pair 64.
Certain embodiments of the nano/micro actuator 70 are configured to mechanically displace or reposition the nano/micro contact bar 72, which acts to support portions of the nano/micro relay switch pair 64, between their respective normal and actuated positions. Certain embodiments of the nano/micro actuator 70 of the nano/micro electro-mechanical relay 60 acts to transition the nano/micro relay switch pair 64 into their actuated positions by bending the nano/micro actuator 70, and thereby displacing the nano/micro contact bar 72 and the attached nano/micro relay switch pair 64, out of or into the paper relative to the viewer. Displacements by which the nano/micro contact bar 72 that supports the NO nano/micro relay switch 80 and NC nano/micro relay switch 82, acts to displace such relay switches 80, 82 out of or in to the paper in
As soon as the nano/micro actuator 70 ceases applying the actuating force it is no longer being deflected into the actuated position, and it returns to the normal position due largely to the spring constant or stored elastic energy of the actuatable segment 68 and can be augmented through applying a voltage (less than the coercive voltage of the piezoelectric layer 205) in the opposite polarity of the aforementioned actuation voltage. The nano/micro contact bar 72 (supporting the displaceable portions of the NO nano/micro relay switch 80 and NC nano/micro relay switch 82) then returns from the actuated position to their normal position. Since both the NO nano/micro relay switch 80 and the NC nano/micro relay switch 82 are supported by and attached to the nano/micro contact bar 72. As the nano/micro contact bar 72 transitions between the normal and actuated positions, so do the NO nano/micro relay switch 80 and the NC nano/micro relay switch 82. An array of the nano/micro relay switch pairs 64 could be provided. Provided each one of the nano/micro relay switch pair 64 in the array were being simultaneously actuated or deactuated, the various relay switches could act simultaneously. Such simultaneous actuation and de-actuation would be important for such data-centric applications as memories, data transfers, shift registers, microcomputers, etc.
The at least one substrate 120 supports the nano/micro actuator 70, the nano/micro contact bar 72, and the anchored contact segment 74. The layers of the anchored contact segment 74 are attached to the substrate 120, and can be considered a unitary portion. During operation, the anchored contact segment 74 exhibits little or no flex due to the connection to the substrate 120. The anchored contact segment 74 each has a number of NO conductive traces 84a and 84b (both in electric communication with the NO nano/micro relay switch 80); as well as a number of NC conductive traces 84c and 84d (both in electric communication with the NC nano/micro relay switch 82 mounted thereupon).
Certain embodiments of the nano/micro actuator 70 includes the layers of the piezoelectric stack layers 94 combined with the layers of the elastic layers 102. All adjacent layers referenced relative to the figures as 201, 202, 203, 204, 205, and 206 are illustrated as being attached or bonded to adjacent layers, so the layers may be viewed as moving as a unitary non-homogenous member forming the nano/micro actuator or the nano/micro contact bar.
Certain embodiments of the nano/micro actuator 70 rely, during actuation, upon the interaction between the elastic layers 102 and the piezoelectric stack layer 94. In general, the elastic layers 102 are easily laterally bendable (bend up and down as viewed in
Certain embodiments of the set of elastic layers 102 include a first elastic layer 201, a second elastic layer 202, and a third elastic layer 203. The structure of the first elastic layer 201, the second elastic layer 202, and the third elastic layer 203 also extends into the nano/micro contact bar 72. The first elastic layer 201 can include, for example, silicon dioxide or other suitable material that might be but does not have to be a dielectric material. The second elastic layer 202 can include, for example, silicon nitride or other suitable material that might be but does not have to be a dielectric material. The third elastic layer 203 can include, for example, silicon dioxide or other suitable dielectric to act as an electric insulator and limit electric current flowing from the actuator electrode layer 204 through the elastic layers 102, conductive traces 84, the substrate 120, and/or electric ground attached to the substrate. Though three layers 201, 202, and 203 are illustrated in the elastic layers 102, a greater of lesser number of layers could be used, and the number of layers or configuration of these layers represents a design choice. It is important that at least one of these layers includes a dielectric material for the above electrical insulating reason. The particular materials or thicknesses as described relative to
The piezoelectric stack layers 94 contracts when a suitable electric voltage is applied between the actuator electrode layers 204 and 206 to actuate the piezoelectric stack layers 94 of the nano/micro actuator 70. Each of the layers forming both the elastic layers 102 and the piezoelectric stack layers 94 (i.e., 201, 202, 203, 204, 205, and 206) may be viewed as bonded to their adjacent layers or layer. As such, as the piezoelectric actuator layer 205 starts contracting during actuation (caused by a suitable bias voltage being applied across actuator electrode layers 204 and 206), the elastic layers 102 tend to deflect laterally in the general direction shown by arrow 124 in the direction towards the contracting piezoelectric stack layers 94. In addition to the nano/micro actuator 70 being deflected, the nano/micro contact bar 72 is also forced upwards, that in turn displaces deflectable portions of both the NO nano/micro relay switch 80 and NC nano/micro relay switch 82 upwardly into their actuated positions.
Such deflection can result in, for example, the NO nano/micro relay element being deflected to its closed position or alternately in a NC nano/micro relay element position being deflected to its open position. Such deflection can occur under the influence of distortion of the nano/micro actuator 70, and can require some degree of flexibility within each of the deflectable elements of the actuatable segment 68, such as between the nano/micro actuator 70 and the associated nano/micro contact bar 72. Making the elastic layers 102 of the nano/micro actuator 70 and/or the nano/micro contact bar 72 suitably flexible can at least partially enable such deflections by the nano/micro actuator 70.
Certain embodiments of the nano/micro electro-mechanical relay 60 are secured on and mounted to the substrate 120. The substrate 120 includes support substrate faces 121 formed thereupon, with a release etch trench 122 formed within a portion of the support substrate face. A considerable portion of the nano/micro actuator 70 and the nano/micro contact bar 72 is formed above the release etch trench 122 and as such is not affixed to the substrate 120, and can thereby be deflected by pressure applied by the nano/micro actuator 70 including the piezoelectric stack layers 94 as shown at 124.
The entire length of the anchored contact segments 74 is attached to the substrate 120, and as such the anchored contact segments remains stationary relative to the substrate. The anchored contact segments 74 is therefore not susceptible to deflections from applied forces from the nano/micro actuator 70 in a direction represented generally by arrow 124. Within this disclosure, any pad or cantilever that is affixed to the anchored contact segment 74 is referred to respectively as a substrate anchored pad or substrate anchored cantilever. During actuation, the nano/micro actuator 70 exhibits a bowing deflection depending upon the configuration of the piezoelectric stack layers 94, that results in deflection of the nano/micro contact bar 72 as well as the supported portions of the NO nano/micro relay switch 80 and NC nano/micro relay switch 82 that are displaced during actuation, as shown by arrow 118. Within this disclosure, pads or cantilevers that are affixed to the NO nano/micro relay switch 80 or the NC nano/micro relay switch 82, and therefore move along with the switches can be referred to as displaceable contact pads (also contact pads) or displaceable contact cantilevers (also contact cantilevers).
Certain stationary portions of the NO nano/micro relay switch 80 and NC nano/micro relay switch 82 (such as substrate anchored cantilevers and substrate anchored pads, as described below) are supported by and remain stationary relative to the anchored contact segments 74. This relative deflection with respect to a fixed surface causes both the NC nano/micro relay switches 82 and the NO nano/micro relay switches 80 to change states. By comparison, support substrate face 121 of the substrate 120 supports, and is attached to, virtually the entire anchored contact segment 74, and thereby the anchored contact segment 74 remains relatively rigid during actuation. The anchored contact segment 74 is maintained substantially fixed along most of its surface area to the substrate 120, and therefore any motion by the other nano/micro relay switches 80, 82 can be countered by the anchored contact segment 74 as if it is a part of the substrate 120.
During operation, the NO nano/micro relay switch 80 remains in its normal open state until actuated, at which time it is displaced into its closed state. Conversely, the NC nano/micro relay switch 82 remains in its closed state until actuated, at which time it is displaced into its open state. As a result of concurrent movement of all members being actuated from the nano/micro contact bar 72, actuation can simultaneously actuate or deactivate both the NO nano/micro relay switches 80 and the NC nano/micro relay switches 82. There can be a variety of arrangements, materials, and configurations of NO nano/micro relay switches 80 and/or NC nano/micro relay switches 82 (or even extensive or varied arrays in certain embodiments).
Certain embodiments of the nano/micro actuator 70, when actuated or de-actuated such as by an application of electrical current, can be configured to cause a corresponding deflection of at least a portion of the nano/micro contact bar 72 as shown by arrow 118. The nano/micro actuator 70 can be configured to include the piezoelectric actuator layer 205 or other similar material, such as to provide a contraction based on application of electric voltage. Internal flexibility of the elastic layers 102 provides for deflection of the nano/micro actuator 70 and the nano/micro contact bar 72. Particularly, during actuation, the nano/micro actuator 70 contracts causing the nano/micro actuator 70 to flex upwardly and generally forcing the nano/micro contact bar 72 such as including supporting the NO nano/micro relay switch 80 and the NC nano/micro relay switch 82 to be displaced upwardly in the direction of the arrow 124 during actuation. To deactuate certain embodiments of the NO nano/micro relay switch 80 and NC nano/micro relay switch 82, the opposed process to that described in this paragraph is followed such that the nano/micro contact bar 72 is returned to its normal position from its actuated position. The overall configurations, dimensions, and materials of the piezoelectric stack layer 94 relative to the elastic layers 102 are selected to determine the amount of displacement of the nano/micro relay switches 80 and 82.
Within this disclosure,
During operation, the NO contact pad 208 (and also the conductive counter dimples 98a,b attached thereto) is deflected between normal and actuated positions in a direction shown by arrow 118 by the nano/micro contact bar 72. A closed circuit defining the NO nano/micro relay switch 80 is formed as the conductive counter dimple 98a comes in close electrical proximity with, or contacts, the conductive dimple 97a; and the conductive counter dimple 98b also comes in close proximity (or contact) with the conductive dimple 97b. Upon this electrical contact or proximity of the nano/micro switch contacts 96a and 96b, a closed circuit defines the NO nano/micro relay switch 80 around a loop including the NO conductive trace 84a, the NO substrate-anchored cantilever 210a, the conductive dimple 97a, the conductive counter dimple 98a, the NO contact pad 208, the conductive counter dimple 98b, the conductive dimple 97b, the NO substrate-anchored cantilever 210b, and the NO conductive trace 84b.
The field of electrical contacts is generally well understood by those skilled in the art. As such,
Considering the embodiments of the nano/micro electro-mechanical relay 60 including the nano/micro relay switch pair 64 as described with respect to
NO nano/micro relay switches 80 can be simultaneously actuated with the NC nano/micro relay switches 82. Such simultaneous actuation and deactuation of multiple nano/micro relay switches (or even arrays thereof), between their normal states and actuated states, would be highly desired for digital logic circuits that often rely upon having a variety of logic gates operate simultaneously for each device, where many of the devices act in concert is well known throughout the computer, controller, automation, robotics, and other such digital applications. This disclosure thereby can be used to provide a variety of digital relay circuits 79, comprising pairs of NO nano/micro relay switches 80 and NC nano/micro relay switch 82. Integral digital relay circuits 79 can contribute to form a variety of digital devices such as adders, memory elements, microcontrollers, and even combinations of such devices as described in this disclosure.
Certain embodiments of the nano/micro electro-mechanical relay 60 can be used to perform digital operations. A true Boolean value can be defined by the output voltage being greater than an average voltage value. A false Boolean value can be defined by the output voltage being less than the average voltage value. Certain embodiments of the nano/micro electro-mechanical relay 60 can function as a six terminal device that can provide digital logic. Two NC conductive traces 84c, 84d can be referred to as normally closed outputs. Two NO conductive traces 84a, 84b can be referred to as the normally open outputs. Based on wiring, certain embodiments of the nano/micro electro-mechanical relay 60 can perform all 16 uniquely differentiable 2-input Boolean functions.
An electrical voltage bias can be applied to certain embodiments of the nano/micro electro-mechanical relay 60 to reduce the overall swing voltage necessary to change between normal and actuated states. Such electrical voltage bias causes a reduction in dynamic power necessary to change the states between normal and actuated. The total power is reduced by using the nano/micro electro-mechanical relay 60 configuration since the leakage current (which can be equated to leakage power) of the electrical voltage bias that is applied between the actuator electrode layers 204 and 206 through the piezoelectric actuator layer 205 is very low. Applying such electrical voltage bias reduces switching time, since less charge is necessary to transition the nano/micro actuator 70 from one state to another, and also because the gap is reduced between conductive dimple 97 and conductive counter dimple 98. From this, the general electro-mechanical operation of certain embodiments of the nano/micro switch pair 64 can be very good whether being used digitally such as in arrays, or being used as discrete devices.
Certain embodiments of the nano/micro electro-mechanical relay 60 can be used as a low-leakage technique for clock-gating either a pure mechanical, or a hybrid mechanical-electronics system to reduce the overall power consumption and provide capacitance. Certain embodiments of the nano/micro electro-mechanical relay 60 can also be used as a low-leakage method for removing parts of a system from a power grid, or other electrical circuits. As such, the nano/micro electro-mechanical relay 60 can provide electrical isolation.
Certain embodiments of the NC nano/micro relay switch 82, as described with respect to
A certain percentage of relatively high-frequency electrical signals applied to either conductive trace associated with NO or NC nano/micro relay switches 80, 82, when open, flows to the corresponding conductive trace due to electrical capacitance formed across capacitive plates (formed by the conductive dimple 97 and the conductive counter dimple 98) of the included nano/micro switch contact 96. By comparison, lower frequency signals are nearly entirely attenuated by the capacitance of the capacitive plates formed by the nano/micro switch contact 96 associated with NO or NC nano/micro relay switches 80, 82 (when open). As such, spacing between the conductive dimple 97 and the conductive counter dimple 98 can be selected, designed, or adjusted to vary the frequencies of signals transmitted or attenuated through each nano/micro switch contact 96 (when in the open position). The above describes one embodiment of capacitive coupling as provided by the conductive dimple 97 and the conductive counter dimple 98. By comparison, a capacitive coupling can also exist, as well as be designed for, between or within the conductive trace lines 84a to 84d, 84f, and 84h for similar purposed, for example.
Both the NO set including the NO substrate-anchored cantilever 210 and NO conductive traces 84c, f; as well as the normally closed set including NC contact cantilever 209 and its NC conductive traces 84c and 84h, may be viewed as forming a single contact point where the voltages are at a single level when the respective NO nano/micro relay switches 80 are actuated or closed.
The location, configuration, and dimensions of the piezoelectric stack layers 94 define the operational characteristics of the nano/micro actuator 70. Those embodiments of the nano/micro actuator 70 that have the piezoelectric stack layers 94 deposited thereupon contributes to the bending of the nano/micro actuator 70. As such, different nano/micro electro-mechanical relay 60 may be configured differently during fabrication by having different length, width, depth, or other configuration of the nano/micro actuators 70. Those nano/micro electro-mechanical relays 60 with longer nano/micro actuators 70 would require a lesser voltage to transition between normal and actuated states. The voltage level at which the voltage that each active nano/micro relay switch 80, 82 transitions between normal and active states could be designed, calibrated, or confirmed.
A variety of NO nano/micro relay switches 80 can be configured as an analog to digital (ND) converter in which the calibrated transition value for each device could be determined. Different ones of the NO nano/micro relay switches 80 have nano/micro actuators 70 that have different lengths or other dimensions, and each NO nano/micro relay switch 80 deflects a different distance based on their length at a given bias voltage with those NO nano/micro relay switches 80 having a longer nano/micro actuator 70 deflecting further at the same bias voltage. The maximum deflection can be set for each NO nano/micro relay switches 80, in certain embodiments. The established ranges set up between the calibrated values for successive NO nano/micro relay switches 80. As such, during operation, all those different NO nano/micro relay switches 80 whose calibrated voltage value is below that of the applied voltage would be actuated, and those different nano/micro relay switches 80, 82 whose calibrated voltage value is above that of the applied voltage would not be actuated. For instance, assuming that there are eight NO nano/micro relay switches 80 for a particular ND converter, between 0 and 8 NO nano/micro relay switches 80 is closed at any given voltage. A digital output value of “11100000” would indicate that the actual analog value is between the calibrated value of the third NO nano/micro relay switch 80 and the fourth. The range above the nano/micro relay switches 80, 82 with the highest calibrated voltage value would indicate the range of the actual applied voltage in a digital manner.
There are a number of nano/micro electro-mechanical digital relay circuits 66 that can be configured with one or more nano/micro electro-mechanical relays 60.
During operation, the voltage supplied by voltage source 302 incrementally increases Vout, which is also applied at the electric contact of the actuator electrode layer 206. The actuator electrode layer 204 is grounded. Vout builds to a level actuating the nano/micro actuator 70, which actuates the NO nano/micro relay switch 80 causing the latter to close. Once the NO nano/micro relay switch 80 closes, the voltage at Vout discharges through the low resistance resistor 306 providing a low resistance pathway to ground and quickly returning the NO nano/micro relay switch 80 to its normal, open condition. The operation process of this paragraph repeats itself to produce the oscillation.
During operation of the dynamic latch 320, the normal state of the nano/micro electro-mechanical relay 60 allows the input terminal 324 to charge or discharge the capacitive element 322 while isolating the output terminal 326. By comparison, when activated, the nano/micro electro-mechanical relay 60 isolates the input terminal 324 from charging or discharging the capacitive element 322, and the output terminal 326 electrically couples to charge or discharge the capacitive element 322. In this configuration, the nano/micro electro-mechanical relay 60 acts both as data storage and retrieval. This device utilizes only one nano/micro electro-mechanical relay 60, which compares to in CMOS design where at least 2 MOSFETS (and typically 4 to limit signal degradation) would be used. The dynamic latch 320 configured with the capacitive element 322 would be expected to maintain its charged state (or uncharged state) for a considerable time such as to allow a temporary interruption in power.
An output terminal 346 is in electrical communication with NO conductive trace 84a of the dynamic latch 360. The NC conductive trace 84d of dynamic latch 360 electrically communicates to the actuator electrode layer 204 of the buffer dynamic latch 360. The output phase terminal 348 electrically couples to actuator electrode layer 204 of the dynamic latch 360. The buffer 360 acts to drive higher capacitance loads within the capacitive element 322, and would allow the data to be maintained for an extended period (e.g., perhaps hours) that is related to leakage through piezoelectric actuator layer 205 of the dynamic latch 360. The buffer 362 also allows new data to be written into and maintained for a considerable duration by the capacitive element 322 of the dynamic latch 360, while the previous piece of data is being used elsewhere in the nano/micro electro-mechanical digital relay circuit 66. As such, the dynamic latch with buffer 340 includes two nano/micro relay switch pairs 64, instead of certain current CMOS designs that use at least 4 MOSFETS, and typically 6 to limit signal degradation.
Additionally, though not shown, two dynamic latches with buffer 340, of the type described with respect to
Various elements, devices, modules and circuits are described above in associated with their respective functions. These elements, devices, modules and circuits are considered means for performing their respective functions as described herein.
While the foregoing is directed to embodiments of the present invention, other and further embodiments of the invention may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.
The invention described herein may be manufactured, used and licensed by or for the U.S. Government.
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Number | Date | Country | |
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20120325630 A1 | Dec 2012 | US |