1. Field of the Invention
The present invention relates to the field of microrelays.
2. Prior Art
Microrelays are currently being developed for low frequency and RF switching applications. A class of these devices is operated by electrostatic force and provides low form factor, low power consumption and excellent signal isolation capabilities. In general, electrostatic microrelays consist of four electrodes and an actuator (four terminal devices). Two electrodes, called the actuation electrodes, provide the attractive force for the actuator on application of an electric potential (voltage) difference between an electrode on the actuator and a fixed actuation electrode. The other two electrodes, called contact electrodes, switch the signal of interest when contacted and shorted together by an otherwise isolated, conductive area on the actuator. Such electrostatically operated microrelays have great potential in various markets, including automatic test equipment and telecommunications markets.
Typically in a microrelay, the contacts have to be at least 10 microns apart in the relay switch open condition to achieve good electrical breakdown and isolation performance. One known fabrication technique involves forming the actuator on a substrate, the actuator being separated from the substrate by a sacrificial layer that is etched away near the end of the fabrication process. However, increasing the gap between the actuator switching electrode and the fixed switching electrodes requires very thick sacrificial layers during the fabrication process, which is a non-trivial operation. Other schemes such as forming a wedge actuator with a controlled bending of the released actuator by built in stress layers is also difficult to control.
In addition, electrostatically operated microrelays can exhibit erratic operating characteristics if not suitably energized. In particular, the actuator electrodes providing the electrostatic operating force due to the voltage difference between the electrodes should not touch, as touching will short out the voltage difference, potentially damaging the relay and at best, temporarily removing the electrostatic actuating force. One way to avoid this is to put a layer of insulation on one or both actuating electrodes. However electric charge can build up on the insulating layers, providing a substantial electrostatic force on the actuator when the actuating electrodes are at the same voltage, or detracting from the electrostatic force on the actuator when the actuating electrodes are at intended actuating voltage differences. This effect can be minimized by grounding one electrode and driving the other electrode with a zero average voltage square wave, or driving the two actuating electrodes with complementary zero average voltage square waves. However, because the electrostatic force obtained is proportional to the square of the voltage difference between the actuating electrodes, the electrostatic force, when present, is always attractive. There is no repelling force that may be generated to open and hold the microrelay relay contacts open.
Microrelays and microrelay fabrication and operating methods providing a microrelay actuator positively controllable between a switch closed position and a switch open position. The microrelays are a five terminal device, two terminals forming the switch contacts, one terminal controlling the actuating voltage on an actuator conductive area, one terminal controlling the actuating voltage on a first fixed conductive area, and one terminal controlling the actuating voltage on a second fixed conductive area deflecting the actuator in an opposite direction than the first fixed conductive area. Providing the actuating voltages as zero average voltage square waves and their complement provides maximum actuating forces, and positive retention of the actuator in both actuator positions. Various fabrication techniques are disclosed.
a through 3g illustrate various exemplary alternate spring configurations for the actuator.
In accordance with the present invention, a five electrode microrelay is provided. The microrelay is comprised of an actuator in the form of a microspring supported and/or flexible region between first and second opposing faces on the interior of a hermetically sealed package. Of the five electrodes, four electrodes correspond to the four electrodes commonly used in the prior art, namely first and second electrodes making contact with a conductive region on the actuator and a cooperatively disposed conductive area on the first opposing face, respectively, to provide the actuating electrodes for the device, and third and fourth electrodes on the first opposing face forming the switch contacts which are closed by contact by another conductive region on the actuator. In addition, in the present invention, a fifth electrode is provided, providing contact to a conductive area on the second opposing face. The conductive area on the second opposing face is adjacent the conductive area on the actuator connected to one of the actuating electrodes. In this way, a voltage difference between the first and second electrodes will deflect the actuator to close the microrelay switch, and a voltage difference between the first and fifth electrodes will deflect the actuator to open the microrelay switch and hold it open.
The use of the fifth electrode provides a number of advantages. It allows attracting the actuator to either extreme of its deflection in normal operation, so that in its free state, the actuator need not provide the normally required switch open contact separation. This eases some accuracy requirements for the free state position, and if the actuator is fabricated on a semiconductor substrate, reduces the thickness of the sacrificial layer that must be removed to free the actuator from the substrate on which it is formed. It also may decrease the microrelay's sensitivity to vibration and make its switching action more positive by holding the actuator against fixed stops in both actuator positions. This avoids actuator vibration when in the switch open position, thereby providing a more positive switching action and avoiding a possible buildup of resonance deflections when used in a vibration environment.
The fifth electrode described above provides a third microrelay actuation electrode, considering the first actuation electrode to be coupled to a conductive area on the first opposing surface and the second actuation electrode coupled to a conductive area on the actuator.
Now referring to
In the embodiment shown in
Sandwiched between top cap 20 and bottom cap 22 in this embodiment is a conductive silicon member 24 with integral actuator member comprised of silicon regions 52 and 54 electrically separated by oxide regions 56, or alternatively by multiple trenches filled with an oxide. Silicon region 54 has a metallized region 58 on the lower surface thereof, with silicon region 52 having small oxide regions or bumps 60 and 62 on opposite surfaces thereof. The entire actuator is supported on spring regions 64, better seen in the bottom face view of the silicon member of
The microrelay of
The use of DC actuation voltages, however, has a tendency to cause the buildup of charge on insulative layers, and accordingly is not preferred. For this purpose, one could instead apply a square wave to metalized region 26, the same wave shifted 180° on region 44, and switch the voltage applied to the silicon regions 52 between these two square waves.
Also as previously mentioned, except for the switch elements themselves, the conductive regions on the actuator should not contact the conductive actuation regions on the top and bottom caps, as such contact will short out the actuation voltage with undesirable, if not catastrophic, effect. Thus, the small oxide regions or bumps 60 and 62 are provided, rather than a full insulative region separating the conductive actuation regions to provide the desired electrically insulating effect while minimizing the amount of insulation used. Of course, the number and position of the bumps may be chosen as desired to avoid such contact.
The preferable form of excitation of the microrelay of
A more preferred form of actuation control for the microrelays of the present invention is to provide a zero average voltage square wave excitation to the conductive regions 52 on the actuator and a complementary (shifted 180°) zero average voltage square wave on the respective fixed conductive areas (26 or 44) for attraction of the actuator to the microrelay switch closed and microrelay switch open positions, respectively. For switch closure, the attractive force between conductive regions 52 on the actuator and conductive regions 44 on the top cap 20 may be minimized by providing the same phase zero average voltage square wave excitation to the conductive regions 44 as on the conductive regions 52 of the actuator. Similarly, for switch open purposes, the attractive forces between the actuator and conductive regions 26 on the bottom cap 22 may be minimized by providing the same zero average voltage square wave excitation to conductive regions 26 as provided to the actuator conductive regions 52 to hold the switch open.
The use of a zero average voltage square wave on the actuator and one of the fixed actuation conductive regions and a complementary zero average value square wave on the other fixed actuation conductive region has substantial advantages, particularly if the square wave voltage usable is limited by the available power supply voltage and not by breakdown or arcing between conductive regions used for actuation. In particular, while the average voltage difference between a zero average voltage square wave and a zero voltage is equal to the voltage of the square wave, the average voltage difference between a zero average voltage square wave and its complement is twice the voltage of the square wave, thereby providing four times the actuation force. Actually, in the present invention, the force of the actuator spring suspension further aids the initial motion of the actuator from either extreme position.
As pointed out, square wave voltages have certain advantages. However they may also have certain disadvantages in some respects. By way of example, square waves have a very broad frequency spectrum, and might give rise to noise in a system utilizing the microrelays of the present invention. Therefore voltage waveforms differing from square waves are also attractive. Sine waves could be used, though the force developed for a given peak to peak voltage difference of equal and out of phase sine waves is only 50% of that of out of phase square waves of the same peak to peak voltage difference. Other symmetric waveforms, also preferably with zero average DC value (relative or absolute), may be used, such as, by way of example, square waves from which the higher frequency components have been filtered out or suppressed. Such waveforms could provide a force approaching that of out of phase square waves of the same peak to peak voltage, be easily generated by filtering or frequency limiting the switching signals provided for microrelay actuation, and may not necessarily contain frequency components higher or at least much higher than the frequency of a sine wave required to effectively smooth out the effects of the resulting sine squared force. In that regard, the waveforms used may be symmetric or unsymmetric, as desired.
Finally, it should be noted that in the foregoing discussion of some of the many excitation options for actuating the microrelays of the present invention, whether by DC voltages, square waves, etc., in general it was implied that on an instantaneous basis, the voltage difference between one of metalized regions 26 and 44 and the silicon regions 52 should be zero while an actuation voltage difference is applied between the other of regions 26 and 44 and the silicon regions 52. In practice, the zero voltage difference need only be very roughly approximated. Specifically, because of the square law of force versus voltage difference, if the voltage difference tending to resist actuation is as high as 25% of the voltage difference encouraging actuation, then the retarding force is only approximately 6% of the actuating force. This 6% is rather trivial, though could be made up, if necessary, by simply raising the actuating voltage by 3%.
As another example of the foregoing, consider a case where a ±5 volt supply is available while the logic signals for actuation of the microrelay are ±3 volt actuation signals. If ±3 volts are used for metalized regions 26 and 44 and ±3 volts are used for the silicon regions 52, the relative actuating force will be 62 or 36 units of force. If possible breakdown or arcing is not a problem, then if ±5 volts are used for metalized regions 26 and 44 and ±3 volts are used for the silicon regions 52, the relative actuating force will be 82−22 or 60 units of force, an increase in the actuating force of 67%. Thus equal amplitudes are not required, and in some cases, intentional use of substantially different amplitude waveforms may well be advantageous from a design and/or performance standpoint. Further, AC waveforms need not be identical in shape. By way of example, AC squarewaves might be subjected to different attenuation of the high frequency components, or a filtered square wave on one conductive area might be used with a sine wave on the adjacent conductive area for attractive purposes.
The embodiment illustrated in
The embodiment illustrated in
The top cap 20 may be readily fabricated by etching the cavity shown and depositing and patterning a metal layer. The silicon actuator may be fabricated starting, by way of example, with a p-type silicon substrate with a thin p++ epi layer on one surface, with a further p-type epi layer thereover. In this fabrication technique, the upper surface of silicon member 24 of
Note that while four springs 64 are shown in
The glass bottom cap 22 may be initially fabricated in a manner similar to that of the glass top cap 20, by etching to form the recess and depositing and patterning the metal layers. (In a preferred embodiment, the metal switch pads 32 and 34 are of a noble metal such a gold, though the metal actuation regions need not be.) Then the bottom cap 22 may be anodic bonded to the silicon member 24 to hermetically seal the microrelay, after which the bottom cap may be ground back to a thickness such as on the order of 50 to 100 microns. Then contact openings may be formed in the glass bottom cap using the metal layers as an etch stop without loosing hermeticity, metal deposited and etched to fill the openings so formed (forming metal vias 48, 28, 40, 42 and 68), and solder balls 46, 30, 36, 38 and 66 formed to complete the microrelays, ready for dicing.
As one alternate embodiment, the recesses initially formed in either or both of the glass caps 20 and 22 may be instead formed on one or both surfaces of the silicon member 24, though a recess in the silicon member facing bottom cap 22, if used, would need to be formed in the epi layer after etching to the p++ layer and subsequently removing the p++ layer.
As a further alternate embodiment, the microrelay may be fabricated from two members, a silicon top cap and actuator, and a glass bottom cap (referenced to
Now referring to
The electrical switch contact metals 80 may be single layers or multiple layers of more than one metal or metal alloy (see
The foregoing description is intended to be illustrative only of certain exemplary embodiments, and not by way of limitation of the invention, as numerous further alternative embodiments in accordance with the invention will be apparent to those skilled in the art. Thus while certain preferred embodiments of the present invention have been disclosed herein, it will be obvious to those skilled in the art that various changes in form and detail may be made in the invention without departing from the spirit and scope of the invention as set out in the full scope of the following claims.
This application is a continuation-in-part of U.S. patent application Ser. No. 10/645,993 filed Aug. 22, 2003 now U.S. Pat No. 6,841,839, which is a divisional of U.S. patent application Ser. No. 10/253,728 filed Sep. 24, 2002, now U.S. Pat. No. 6,621,135 issued Sep. 16, 2003.
Number | Name | Date | Kind |
---|---|---|---|
5278368 | Kasano et al. | Jan 1994 | A |
5367429 | Tsuchitani et al. | Nov 1994 | A |
5479042 | James et al. | Dec 1995 | A |
5544001 | Ichiya et al. | Aug 1996 | A |
6162657 | Schiele et al. | Dec 2000 | A |
6239685 | Albrecht et al. | May 2001 | B1 |
6396372 | Sakata et al. | May 2002 | B1 |
6486425 | Seki | Nov 2002 | B2 |
6633212 | Ruan et al. | Oct 2003 | B1 |
6734513 | Seki et al. | May 2004 | B2 |
6734770 | Aigner et al. | May 2004 | B2 |
6872902 | Cohn et al. | Mar 2005 | B2 |
20020160549 | Subramanian et al. | Oct 2002 | A1 |
20030006868 | Aigner et al. | Jan 2003 | A1 |
20040113732 | Delamare et al. | Jun 2004 | A1 |
Number | Date | Country | |
---|---|---|---|
20050121298 A1 | Jun 2005 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 10253728 | Sep 2002 | US |
Child | 10645993 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 10645993 | Aug 2003 | US |
Child | 10979307 | US |