The invention relates to a microswitch comprising:
Microswitches are very widely used, in particular in the telecommunications field for signal routing, impedance matching networks, amplifier gain adjustment, etc. The frequency bands of the signals to be switched can range from a few MHz to several tens of GHz.
Conventionally, microswitches coming from microelectronics and used for radio-frequency circuits are able to be integrated with the circuit electronics and have a low manufacturing cost. Their performances are however limited.
For example, FET (Field Effect Transistor) type microswitches, made of silicon, can switch high-power signals at low frequency only. MESFET (Metal Semiconductor Field Effect Transistor) type microswitches, made of gallium arsenide (GaAs), operate well at high frequency, but only for low-level signals. In a general manner, above 1 GHz, all these microswitches present a high insertion loss in the closed (on) state, around 1 dB to 2 dB, and a fairly low insulation in the open (off) state, of about −20 dB to −25 dB.
To remedy these shortcomings, MEMS (Micro Electro Mechanical System) type microswitches have been proposed, which on account of their design and operating principle present the following features: low insertion loss (typically less than 0.3 dB), high insulation (typically greater than −30 dB), low consumption and linearity of response.
Two main actuating principles are known for such MEMS type microswitches, i.e. electrostatic actuation and thermal actuation. Microswitches with electrostatic actuation present the advantage of having a high switching rate and a relatively simple technology. They do however encounter problems of dependability, in particular due to an increased risk of sticking of the microswitch structure, and they only allow small movements. Microswitches with thermal actuation present the advantage of having a low actuation voltage (less than 5V), a high energy density and a large deflection amplitude, but they do encounter problems of excessive consumption and present a low switching rate.
To remedy these shortcomings, it has been proposed to combine these two major types of microswitches and to provide a microswitch with thermal actuation and electrostatic holding.
As represented in FIGS. 1 to 3, a microswitch 1 conventionally comprises a deformable membrane or beam 2, attached to a substrate 3 via the two ends thereof. Actuating means 4 enable the beam 2 to be deformed, from a first stable position represented in
The actuating means 4 for example comprise thermal actuators 7 operating in conjunction with heating resistors 8 inserted in the ends of the beams 2. The microswitch 1 also comprises complementary electrostatic holding means 9, respectively fixedly secured to the beam 2 and to the substrate 3. The electrostatic holding means 9 are designed to keep the microswitch 1 in the second stable position (
Change of position of the microswitch 1 is represented in FIGS. 1 to 3. In
The different deformation areas of the beam 2 are illustrated in
Most of the electric consumption of the microswitch 1 is thus limited solely to the fraction of time necessary for the microswitch to move from the first stable position (
However, as the holding electrodes 9 are attached to the beam 2, they deform like the beam 2. The area with a small air-gap, i.e. the height between the electrostatic holding means 9 of the beam 2 and of the substrate 3 in the second stable position (
The object of the invention is to remedy these shortcomings and has the object of providing a dependable microswitch presenting a low actuation voltage and a low consumption.
According to the invention, this object is achieved by the accompanying claims and more particularly by the fact that the membrane comprises at least:
Other advantages and features will become more clearly apparent from the following description of particular embodiments of the invention given as non-restrictive examples only and represented in the accompanying drawings, in which:
FIGS. 1 to 3 represent the change of position of a deformable beam of a microswitch with thermal actuation and electrostatic holding according to the prior art.
In FIGS. 5 to 7, a deformable membrane 12 of a microswitch 1 with thermal actuation and electrostatic holding comprises two substantially parallel flexure arms 13 comprising the thermal actuating means 4 of the microswitch 1 at the ends of said arms. The membrane 12 comprises a contact arm 14, between the flexure arms 13, said contact arm being substantially parallel to the flexure arms 13 and preferably comprising two electrostatic holding electrodes 15 arranged on each side of the conducting pad 6 of the membrane 12.
For example, the flexure arms 13 are formed by bimetal strips which present good deformation characteristics under the effect of a temperature variation. The thermal actuating means 4 are for example formed by heating resistors inserted in the ends of the flexure arms 13 of the membrane 12.
As represented in
The contact arm 14 is attached to the flexure arms 13 at the level of the high deformation areas 20 thereof, i.e. in the central parts thereof. The electrostatic holding electrodes 15, situated on this contact arm 14, therefore move in a direction substantially parallel to the substrate 3 and are not deformed, or are hardly deformed, on actuation of the microswitch 1 by thermal effect.
In
The electrostatic forces generated in the small air-gap comprised between the contact arm 14 and the electrostatic holding means 9 of the substrate 3 result in the membrane 12 of the microswitch 1 being held in this position. The electrodes 15 are not deformed, or are hardly deformed, which results in an improved dependability of the microswitch 1.
The embodiment represented in
As represented in
The high deformation areas 20, represented in dark grey, are therefore the ends of the flexure arms 13 fixedly secured to the contact arm 14, whereas the low deformation areas 21, represented in light grey, are the ends of the flexure arms 13 attached to the substrate 3 and comprise the thermal actuating means 4.
The substrate 3 (not shown for this embodiment) is then shaped in such a way as to operate in conjunction with the membrane 12. It comprises a conducting pad 5, facing the conducting pad 6 of the contact arm 14, and electrostatic holding means 9 facing the electrode 15 of the contact arm 14.
Such a deformable membrane 12 according to
Position change of the microswitch 1 according to the embodiments described above takes place as follows. In the first stable position of the microswitch 1, the membrane 12 is substantially horizontal and parallel to the substrate 3, being attached to the latter by the salient edges of the substrate 3. The bimetal strips of the flexure arms 13 are solicited for example by flow of a current in the heating resistors. Actuation of the flexure arms 13 results in deflection of the membrane 12 of the microswitch 1 until contact is made or very nearly made between the conducting pads 5 and 6. A potential difference is then applied between the electrostatic holding electrodes 15, arranged on the bottom surface of the contact arm 14, and the complementary holding means 9 achieved on the substrate 3. Finally, after the power supply to the heating resistors has been stopped, the microswitch 1 remains in its second stable position (
The microswitch 1 comprising a membrane 12 according to
Whatever the embodiment of the microswitch 1, the contact arm 14 supporting the electrostatic holding electrodes 15 is preferably elongate. In the particular embodiment of the microswitch 1 represented in
The different embodiments of the microswitch 1 described above in particular provide the following advantages, i.e. low actuating and electrostatic holding voltage, of about 5V, low consumption, preservation of all the advantages of actuation by bimetal strip (large deflection amplitude, high energy density, low actuating voltage) and fabrication implementing a technology compatible with that of integrated circuits.
Moreover, the microswitch 1 having two stable positions, the first position wherein electric contact is interrupted and the second position wherein electric contact is established, only switching from one position to the other consumes energy and the microswitch 1 can, after actuation, remain in the first stable position without any additional power being provided and remain in the second stable position with a very limited power input (holding voltage) on account of the proximity of the electrodes 15 and of the electrostatic holding means 9 in this position.
The invention is not limited to the embodiments described above. The actuating means 4 of the microswitch 1 can in particular comprise a piezoelectric actuator. The flexure arms 13 then comprise at least one layer of piezoelectric material. They may also be formed by SiN/piezoelectric layer bimetal strips and are provided with excitation electrodes on their top and bottom faces.
In the case of a piezoelectric actuator, a voltage is then applied to the piezoelectric layer of the flexure arms 13 to cause deformation of the flexure arms 13. For example, the materials used to produce the piezoelectric actuator are lead zirconate titanate (PZT), aluminium nitride (AlN) or zinc oxide (ZnO).
Moreover, the membrane 12 can comprise additional flexure arms 13, contact arms 14, electrodes 15 and conducting pads 6, the electrodes 15 and conducting pads 6 still being arranged on the contact arms 14. In the case of a membrane 12 according to
The preferred applications for the microswitch 1 are, in a general manner, all applications using microswitches in the electronics and microelectronics fields, and more particularly radiofrequency applications, i.e. antenna microswitches, transceivers, band microswitches, etc.
Number | Date | Country | Kind |
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0403586 | Apr 2004 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FR05/00815 | 4/4/2005 | WO | 9/22/2006 |