KR100664023B1 - Mems switch to be moved electromagnetic force and manufacture method thereof - Google Patents

Abstract

The present invention relates to an electromagnetic force driven MEMS switch, comprising: a high resistance silicon substrate; At least one coil coupled to the substrate and generating magnetic force in one direction; A signal connection terminal including an input terminal and an output terminal and disposed on one side of the substrate; And a movable unit coupled to the substrate to induce a magnetic force generated by the coil and to turn on / off the signal connection terminal by the induced magnetic force.

According to the present invention, it can be applied to a switching array that can be used at low voltage, can be used in semiconductor measuring equipment by securing high efficiency, low loss, and broadband characteristics, and can also be used at high frequency and compatible with other processes. It can be used in the form of a filter bank of a wireless communication device, and can be easily integrated on a silicon substrate so that it can be fully integrated with a CMOS circuit, and thus it can be widely applied to various fields.

Description

MEMS switch of electromagnetic force driving and its manufacturing method {MEMS SWITCH TO BE MOVED ELECTROMAGNETIC FORCE AND MANUFACTURE METHOD THEREOF}

1 is a plan view schematically showing a structure of an electromagnetic force driven MEMS switch according to an embodiment of the present invention.

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FIG. 2 is a schematic cross-sectional view schematically illustrating an internal structure of the MEMS switch illustrated in FIG. 1.

3 is a view showing a state in which the electromagnetic force of the MEMS switch of the electromagnetic force drive shown in FIG.

4A to 4F are process charts for explaining a method of manufacturing an electromagnetic force driven MEMS switch.

5 is a plan view schematically illustrating a structure of an electromagnetic force driven MEMS switch according to another exemplary embodiment of the present invention, in which a movable core is omitted.
FIG. 6 is a plan view schematically illustrating a structure of the MEMS switch illustrated in FIG. 5.

7 is a plan view schematically illustrating a structure of an electromagnetic force driven MEMS switch according to another exemplary embodiment of the present invention, in which a movable core is omitted.
FIG. 8 is a plan view schematically illustrating a structure of the MEMS switch illustrated in FIG. 7.

FIG. 9 is a plan view schematically illustrating a structure of an electromagnetic force driven MEMS switch according to another exemplary embodiment of the present invention, in which a movable core is omitted.
FIG. 10 is a plan view schematically illustrating a structure of the MEMS switch illustrated in FIG. 9.
FIG. 11 is a plan view schematically illustrating a structure of an electromagnetic force-driven MEMS switch according to another embodiment of the present invention, in which a movable core is omitted.
FIG. 12 is a plan view schematically illustrating a structure of the MEMS switch illustrated in FIG. 11.

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<Description of the symbols for the main parts of the drawings>

100: high resistance silicon substrate

110; 111, 112, 113, 115: fixed core

110a, 110b: Both core parts

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110c: bottom core portion

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120; 121,122,123,125: coil
130; 131,132,133,135: movable core
140; 141,142: Signal connection terminal

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a switch widely used for shielding signals in mobile and telecommunication circuits and semiconductor test equipment. In particular, an electromagnetic force driver having a magnetic core and a coil consisting of a fixed core and a movable core is formed on a high resistance silicon substrate. The present invention relates to a MEMS switch for electromagnetic force driving and a method of manufacturing the same, which are provided at a low voltage by forming a pair of signal connection terminals disconnected at an intermediate portion or one side of the electromagnetic force driver.

In general, the switch is a representative component widely used in most electronic products, ranging from general home appliances to recent wireless mobile communication devices. As the additional functions of various electronic products are added, the switch has a large number of parts even in a single product. This is used.

Among them, FET (Field Effect Transistor) is a switch type of semiconductor type and mainstream with small size and low price. However, the recent emergence of MEMS technology can control the opening and closing of circuit through mechanical driving rather than switching by electric field effect. The MEMS switch has been started to be implemented in the form of a relay, which is generally classified according to the method of generating driving force because mechanical driving occurs directly.

 First, there is the electrostatic drive method which is currently being researched and developed the most. The electrostatic driving method has a basic concept of shielding a circuit by mutual attraction generated by applying voltages of the anode and the cathode to the structure that can be deformed in the elastic region, respectively. The electrostatic drive method has the advantages of low power consumption and simple structure and easy implementation. Since the driving force is generated by the applied voltage difference, several tens of volts or more are required for driving with reliability. Therefore, it is not easy to apply to portable mobile devices such as mobile phones, which require the use of low voltage.

Self-driven MEMS switches have the advantages of low driving voltage, large driving force and displacement, but they are difficult to manufacture due to their complicated structure and high power consumption, which has not been studied much until now. R & D is being actively conducted since these can be improved.

As mentioned above, the self-driven MEMS switch has a disadvantage in that it is difficult to implement structurally, and thus many studies have not been conducted until now.

Therefore, various improvements have to be made to alleviate these shortcomings. First, the area must be minimized and the process steps reduced. Secondly, the maximum cross-sectional area of the coil should be secured and the sheet resistance should be minimized to secure the maximum amount of current and driving force. Finally, thermal dissipation should be maximized by using insulators with the highest possible thermal conductivity.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems and defects. The present invention provides an electromagnetic force driver having a magnetic core and a coil consisting of a fixed core and a movable core on a high resistance silicon substrate, and an intermediate portion of the electromagnetic force driver or An object of the present invention is to provide an electromagnetic force-driven MEMS switch and a method of manufacturing the same, by forming a pair of signal connection terminals disconnected at one side thereof to enable use at a low voltage.

MEMS switch of the electromagnetic force drive according to an embodiment of the present invention to achieve the above object and a high resistance silicon substrate; At least one coil formed on the high resistance silicon substrate and generating magnetic force in one direction; A signal connection terminal disposed on one side of the high resistance silicon substrate; A fixed core part configured of a bottom core part and both core parts disposed at both ends of the bottom core part, respectively, wherein at least one of the two core parts is disposed at the center of the coil to induce magnetic force generated by the coil; It is disposed in a state separated from the substrate on the fixed core portion, it may be configured to include a movable core for turning on / off the signal connection terminal by the magnetic force induced by the fixed core portion.
Here, the coil may be formed such that both core parts disposed on any one side of the bottom core part are disposed in the center, and both core parts disposed on the other side of the bottom core part may be disposed on the outer side of the coil. In addition, the signal connection terminal may be disposed at a position facing both core portions disposed at an outer portion of the coil, and fixed ends of the movable cores may be coupled to both core portions disposed at the outer portion of the coil so that the movable core has a cantilever shape. The signal connection terminal may be configured to be turned on or off.
On the other hand, both core portions may be configured to be respectively disposed at each center of the pair of coils, and the signal connection terminals may be formed at the outer side of the pair of coils, and both core portions disposed opposite the signal connection terminals. The fixed end of the movable core is coupled to the movable core can be configured to turn on / off the signal connection terminal in the form of a cantilever.
On the other hand, the coil may be formed so that each of the two core parts are respectively disposed in the center of the coil, the signal connection terminal may be formed between the coil, the movable core is both ends elastic with the connection portion is provided in the center portion The hinge may be mounted on the upper surface of the substrate so that the intermediate connector can turn on / off the signal connection terminal.
On the other hand, the coil may be formed such that both core parts disposed on either side of the bottom core part are disposed in the center, and both core parts disposed on the other side of the bottom core part may be disposed on the outer side of the coil. have. The signal connection terminal may be disposed at a position facing the cores on both sides of the coil, and the movable core may be mounted on the upper surface of the substrate by an elastic hinge to turn on the signal connection terminal. It can also be configured to be turned on / off.

In one embodiment of a method of manufacturing an electromagnetic force driven MEMS switch according to the present invention, the method comprises the steps of: forming a coil on a high resistance silicon substrate; Forming a fixed core comprising two core parts and a bottom core part on the substrate; Forming a signal connection terminal on one side of the substrate; And forming a movable core in a state separated from the substrate at an upper position of the fixed core.
Here, the coil, the fixed core, and the signal connection terminal may be formed by repeating the pattern formation using the photosensitive process, the formation of a mold using dry etching, the formation of a seed layer for electroplating through sputtering, and the electroplating process.
In addition, the movable core may be formed by performing a process of forming a mold using photoresist and photosensitive polyimide, electroplating, and removing a sacrificial layer.

The present invention uses a high-resistance silicon wafer to insert a conventional coil portion into a wafer, that is, to form a recessed shape in which a groove is inserted into a wafer and a coil is inserted into a conventional polymer / metal type multilayer process. It is easier to implement a three-dimensional structure that eliminates the instability and non-uniformity caused.
In addition, high-resistance silicon acts as an insulator, enabling the implementation of a high aspect ratio conductor structure, thereby reducing electrical resistance, allowing more current to pass, obtaining good driving power, and reducing power consumption. In addition, in the case of using an existing polymer-based insulator, the heat dissipation was not very good due to the high thermal resistance of the polymer itself, but the present invention using the high-resistance silicon brought an improvement in performance to improve such a problem. The use of high-resistance silicon minimizes the loss from the substrate in the high frequency band.

The present invention is an electromagnetic force-driven MEMS switch for application to next generation mobile terminals and reconfigurable systems, and a method of manufacturing the same, unlike conventional semiconductor-type switches, low loss using ultra micromechanical system processing technology. The high isolation, high isolation, and broadband characteristics make it widely applicable to the next generation of mobile and wireless communication systems.

Hereinafter, the MEMS switch of the electromagnetic force driving according to the present invention will be described through the embodiments of the present invention to help understand the features of the present invention as described above.
The present invention is not limited by the embodiments described below, but the present invention can be implemented as an example as described below. That is, the embodiments described below are described on the basis of the most suitable embodiments for understanding the technical features of the present invention, and the present invention is variously modified and combined within the scope of the present invention through the embodiments described below. It is to be understood that embodiments of such variations and combinations are within the scope of the present invention.
In addition, in order to help the understanding of the embodiments described below, in the reference numerals described in the accompanying drawings, elements having different arrangement positions among the components that have the same function are denoted by a number of unified extension lines.

1 to 3 illustrate an electromagnetic force driving MEMS switch according to an embodiment of the present invention. Referring to FIGS. 1 and 2, the structure of the electromagnetic force driving MEMS switch according to the first embodiment of the present invention is illustrated. 3 is an explanatory view of the operation of the electromagnetic force driven MEMS switch.

As shown in the drawing, the electromagnetic force driven MEMS switch according to an embodiment of the present invention includes a coil 120 (121) integrally formed with a high resistance silicon substrate (wafer) 100 and the high resistance silicon substrate 100. And it may include a fixed core (110; 111) for inducing electromagnetic force generated from the coil (120; 121). The fixed cores 110 and 111 include bottom core parts 110c and both core parts 110a and 110b formed at both ends of the bottom core part 110c.
Here, the coils 120 and 121 may be configured such that any one of the two core parts 110a and 110b is positioned at the center of the coils 120 and 121. In addition, the coils 120 and 121 are configured to be wound in a snail shape around the core part (not shown) 110a. In addition, the other opposite core part 110b is configured to be disposed at an outer position of the coils 120 and 121. The two both core parts 110a and 110b are integrally connected by the bottom core part 110c disposed under the coils 120 and 121.
The movable cores 130 and 131 are formed in the cantilever structure by the fixing part 131b in the other both core parts 110b disposed at the outer positions of the coils 120 and 121.
In addition, a signal connection terminal 141 constituting an input terminal at a position facing the other both core parts 110b disposed at an outer position of the coils 120 and 121, and at an outer position of the coils 120 and 121. And a signal connection terminal 140 formed to separate the signal connection terminal 142 constituting the output terminal.
The magnetic force generated in accordance with the direction of the current flowing through the coil (120; 121) by such a configuration from the bottom core portion (110c) from both core portions (110a) located in the center of the coil (120; 121) And the other core parts 110b positioned outside the coils 120 and 121 and the core parts 110a positioned in the center of the coils 120 and 121 again through the movable cores 130 and 131. Is induced to circulate.
As a result of the induced magnetic force, the movable cores 130 and 131 may turn on / off the signal connection terminals 140 and 141 and 142. The direction of the induced magnetic force may be changed in accordance with the direction of the current flowing through the coil (120; 121).

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4A to 4F are process diagrams for explaining an embodiment of a method for manufacturing an electromagnetic force driving MEMS switch according to an embodiment of the present invention described above, each manufacturing process of the electromagnetic force driving MEMS switch device according to the present invention; According to the process of shown separately.

First, as illustrated in FIGS. 4A and 4B, the substrate 100 is etched at an upper position of the high resistance silicon substrate 100 so as to have a structure in which coils 120 and 121 are embedded. On the other hand, the implementation of the structure by the conventional polymer-based mold had a limitation in the high aspect ratio, but the mold through the silicon etching as described above can be realized up to a high aspect ratio of up to 40: 1. Development is required. And to reduce the size of the device and to reduce the electrical resistance to reduce the line width of the coil (120; 121) to form a deep trench (groove) to form a coil through copper electroplating, such as good electrical conductivity.

Subsequently, in the process of FIG. 4C, the fixing cores 110 and 111 are formed on the high resistance silicon substrate 100 through the above steps. In this process, it is possible to implement a plating process using a material having a relatively high permeability such as nickel or a nickel alloy in order to induce as much magnetic current as possible at a low voltage to obtain a high magnetic flux density.

Here, as described above, the two core parts 110a disposed at the central position of the coils 120 and 121, the other two core parts 110b disposed at the outer position of the coils 120 and 121, and the two Both bottom core portions 110c connecting the two core portions 110a and 1100b may be formed at this stage, and as shown in FIG. 4A, the bottom core portion 110c is formed in advance before the bottom core portion 110c is formed. Both core portions 110a and 110b extending vertically at both ends of the portion 110c may be formed in this step.

Subsequently, as shown in FIG. 4D, the signal connection terminals 140; 141 and 142 are formed on the right end of the high resistance silicon substrate 100 so as to be separated from each other.

Subsequently, as shown in FIGS. 4E and 4F, movable cores 130 and 131 having a cantilever structure are formed at one end thereof connected to the left end of the high resistance silicon substrate 100.

Formation of the structure is formed by repeating the formation of a pattern using a photosensitive photosensitive process, the formation of a mold using a dry etching, the formation of a seed layer for electroplating through sputtering, and finally the electroplating process. The process according to FIGS. 4 d, e and f may proceed to the formation of a mold using photoresist and photosensitive polyimide, commonly referred to as surface micromachining technology, and to the electroplating and removal of the sacrificial layer.

The MEMS switch of the electromagnetic force driving according to an embodiment of the present invention as described above is the fixed core (110; 111) disposed at the central position of the coil (120; 121) when a current flows in the coil (120; 121) The magnetic flux is generated in one of the two core parts 110a constituting the cross-over through the movable cores 130 and 131 passing through the bottom core part 110c and the other one core part 110b as shown in FIG. The magnetic flux circulated to the both core parts 110a disposed at the central position of the; 121 flows. At this time, the attraction between the central portion of the coil (120; 121) and the movable core (130; 131) acts on each other, the end of the movable core (130; 131) having a structure of cantilever by such attraction By moving down, the two separate signal connection terminals 140; 141 and 142 are electrically connected.

When the current applied to the coils 120 and 121 is blocked, the attraction force between the central portion of the coils 120 and 121 and the movable cores 130 and 131 is extinguished, and the movable cores 130 and 131 are removed. The signal connection terminals 140; 141 and 142 are disconnected by being restored to their original positions. The operation of the movable cores 130 and 131 enables on / off switching of the signal connection terminals 140 and 141 and 142.

5 and 6 are views showing an electromagnetic force driving MEMS switch according to another embodiment of the present invention, the configuration of which is the movable core (130; 134) is compared with the embodiment shown in Figs. It has a wider width and is formed in a tapered shape in which the front portion gradually narrows down toward the connecting end 134a, and other configurations and actions are the same as in the embodiment.

7 and 8 are diagrams illustrating an electromagnetic force driving MEMS switch according to another embodiment of the present invention. As shown therein, both core parts 110a and 110b and a bottom core of the high resistance silicon substrate 100 are shown. Coils 120 and 122 are formed around both core portions 110a and 110b of the fixed cores 110 and 112 formed to have the portions 110c, respectively, and the outer portions of the coils 120 and 122 are illustrated. Signal connection terminals (140; 141, 142) are formed at the upper right position, and the movable core (130) is disposed at both core parts (110b) positioned on the left side of the core part of the fixed core (110; 112). 132) The fixed end 132b of the rear end is connected, and the connection end 132a of the front end of the movable core 130; 132 is configured to connect the signal connection terminals 140; 141 and 142.
7 and 8 have a fixed core (110; 112) and two coils (120; 122) having two core parts (110a, 110b) for generating two vertical magnetic forces, and moving magnetic A cantilever of a thin film, that is, a fixed end 132b of the movable cores 130 and 132 is connected to both core portions 110b located on the left side of the fixed cores 110 and 112, thereby moving the movable core 130; The connection terminal 132a of the 132 connects the signal connection terminals 140; 141 and 142.

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9 and 10 are diagrams illustrating an electromagnetic force driving MEMS switch according to another embodiment of the present invention, wherein both core parts 110a and 110b and the bottom core part 110c are formed on the high resistance silicon substrate 100. Fixing cores 110 and 113 are formed to be provided. A pair of coils 120 and 123 are formed around the core parts 110a and 110b, and both ends of the movable cores 130 and 133 are elastic hinges 133b to the high resistance silicon substrate 100. The signal connection terminals 140; 141 and 142 are formed at the middle portions of both coils 120 and 123, and are connected by the intermediate connection portions 133a of the movable cores 130 and 133. It is.

9 and 10 configured as described above, two bilateral core parts 110a, 110b and two coils 120 having signal connection terminals 140; 141 and 142 provided in the fixed cores 110 and 113. An elastic hinge 133b having a low spring constant at the four ends of the movable cores 130 and 133 having a magnetic thin film bridge structure, which is arranged at the center of the electromagnetic force driving means having a; 123; The intermediate connecting portion 133a of the movable cores 130 and 133 connects the signal connection terminals 140, 141 and 142.
11 and 12 are diagrams illustrating an electromagnetic force driving MEMS switch according to another embodiment of the present invention, wherein both core parts 110a and 110b and the bottom core part 110c are formed on the high resistance silicon substrate 100. Coils 120 and 125 are formed around both core portions 110a disposed on any one side of the fixed cores 110 and 115, and both ends of one side of the movable cores 130 and 135 are formed of the high resistance. The upper portion of the silicon substrate 100 is flexibly connected to the elastic hinge 135b. The signal connection terminals 140 and 141 and 142 are formed on the outer side of the coil 120 and 125 to the opposite positions of the elastic hinge 135b and are connected by the connection end 135a in front of the movable core 130 and 135. It is configured to be.
11 and 12, the signal connection terminals 140; 141 and 142 configured in a separated state have the fixed cores 110 and 115 and one coil 120 having both core parts 110a and 110b. 125 is a structure located on the side of the coil 120; 125 of the electromagnetic force driver having a 125, and is connected to an elastic hinge 135b having a low spring constant at one end of the movable core 130; 135 of the movable cantilever structure. The movable cores 130 and 135 are elastically rotated by the elastic hinges 135b such that the tip connecting end 135a of the movable cores 130 and 135 turns on / off the signal connecting terminals 140 and 141 and 142.

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As described above, the present invention implements a self-driven MEMS switch that can be used at a low voltage of 3 V or less, thereby securing characteristics of high efficiency, low loss, and broadband, which are disadvantages of the conventional FET switch, thereby enabling the next generation of mobile terminals and expensive semiconductor measurement equipment. It can be applied to switching arrays that can be used in the system, and it is expected to have a great business effect. Compared with other conventional magnetically driven switches, it has a good performance by using a structure that is significantly improved in heat dissipation and power consumption, and can be used at a high frequency and is compatible with other processes, such as a filter bank of a wireless communication device. Can be used as In addition, since it is easy to integrate on a silicon substrate, it is possible to fully integrate with a CMOS circuit, and thus it has an advantage that it can be widely applied to various fields.

Claims (15)

A high resistance silicon substrate; At least one coil formed on the substrate to generate magnetic force in one direction; A signal connection terminal disposed on one side of the substrate; A fixed core part including a bottom core part and both core parts disposed at both ends of the bottom core part, the at least one both core parts being disposed at the center of the coil to induce a magnetic force generated by the coil; And a movable core disposed above the fixed core part to be separated from the substrate and configured to turn on / off the signal connection terminal by a magnetic force induced by the fixed core part. MEMS switch. According to claim 1, The coil is formed so that both core parts disposed on any one side of the bottom core portion is disposed in the center, Both core parts disposed on the other side of the bottom core portion is disposed on the outer side of the coil, The signal connection terminal is disposed at a position facing both core portions disposed at an outer portion of the coil, and fixed ends of the movable cores are coupled to both core portions disposed at the outer portion of the coil such that the movable core is cantilevered. MEMS switch of the electromagnetic force drive, characterized in that configured to be able to turn the terminal on / off. According to claim 1, wherein the two core parts are each configured to be disposed at each center of the pair of coils, the signal connection terminal is formed on the outer side of the pair of coils, both core parts disposed opposite the signal connection terminal And a fixed end of the movable core is coupled to the movable core so as to turn on / off the signal connection terminal in the form of a cantilever. 2. The coil of claim 1, wherein each of the two core parts is formed at the center of the coil, respectively, and a signal connection terminal is formed between the coils, and the movable core is provided at both ends with the connection part provided at the center part. The electromagnetic force-driven MEMS switch, characterized in that mounted on the upper surface of the substrate by an elastic hinge so that the intermediate connection portion can be turned on / off the signal connection terminal. According to claim 1, The coil is formed so that both core parts disposed on any one side of the bottom core portion is disposed in the center, Both core parts disposed on the other side of the bottom core portion is disposed on the outer side of the coil, The signal connection terminal is disposed at a position facing both core parts disposed at an outer side of the coil, and the movable core is mounted at an upper end of the substrate by an elastic hinge to turn on / off the signal connection terminal. MEMS switch is characterized in that the electromagnetic force driven. Forming a coil on the high resistance silicon substrate; Forming a fixed core comprising both core parts and a bottom core part on the substrate; Forming a signal connection terminal on one side of the substrate; And forming a movable core in a state separated from the substrate at an upper position of the fixed core. The method of claim 6, wherein the coil, the fixed core, and the signal connection terminal are repeatedly formed by pattern formation using a photosensitive process, formation of a mold using dry etching, formation of a seed layer for electroplating through sputtering, and an electroplating process. And the movable core is formed by performing a process of forming a mold using photoresist and photosensitive polyimide, and electroplating and removing a sacrificial layer. delete delete delete delete delete delete delete delete

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