Multi-bit phase shifters using MEM RF switches

TECHNICAL FIELD OF THE INVENTION

This invention relates to techniques for introducing phase shifts in RF applications, and more particularly to phase shifting techniques using micro-electro-mechanical switches (“MEMS”).

BACKGROUND OF THE INVENTION

Exemplary applications for this invention include space-based radar systems, situational awareness radars, and weather radars. Space based radar systems will use electronically scan antennas (ESAs) including hundreds of thousands of radiating elements. For each radiating element, there is a phase shifter, e.g. 3 to 5 bits, that, collectively in an array, control the direction of the antenna beam and its sidelobe properties. For ESAs using hundreds of thousands of phase shifters, these circuits must be low cost, be extremely light weight (including package and installation), consume little if no DC power and have low RF losses (say, less than 1 dB). For space sensor applications (radar and communications) these requirements exceed what is provided by known state of the art devices.

Current state of the art devices used for RF phase shifter applications include ferrites, PIN diodes and FET switch devices. These devices are relatively heavier, consume more DC power and more expensive than devices fabricated in accordance with the present invention. The implementation of PIN diodes and FET switches into RF phase shifter circuits is further complicated by the need of additional DC bias circuitry along the RF path. The DC biasing circuit needed by PIN diodes and FET switches limits the phase shifter frequency performance and increase RF losses. Populating the entire ESA with presently available T/R modules is prohibited by cost and power consumption. In short, the weight cost and performance of the currently available devices fall short of what is needed for ESAs requiring electrically large apertures and/or large numbers of radiating elements, e.g. greater than 5000 elements.

Other applications for the invention include switchable attenuators, switchable filter banks, switchable time delay lines, switch matrices and transmit/receive RF switches.

SUMMARY OF THE INVENTION

In accordance with one aspect of the invention, an electronically scanned array is described. The array includes a linear array of radiating elements, with an array of phase shifters coupled to the radiating elements. An RF manifold including a plurality of phase shifter ports is respectively coupled to a corresponding phase shifter RF port and an RF port. A beam steering controller provides phase shift control signals to the phase shifters to control the phase shift setting of the array of the phase shifters. The phase shifters each include a plurality micro-electro-mechanical (“MEM”) switches responsive to the control signals to select one of a discrete number of phase shift settings for the respective phase shifter.

In accordance with another aspect of the invention, an RF phase shifter circuit includes first and second RF ports, and a switch circuit comprising a plurality of micro-electro-mechanical (“MEM”) switches responsive to control signals, said switch circuit arranged to select one of a plurality of discrete phase shift values introduced by the phase shifter circuit to RF signals passed between the first and second RF ports, the circuits connected to provide a single-pole-multiple-throw (SPMT) or multiple-pole-multiple-throw (MPMT) switch function.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other features and advantages of the present invention will become more apparent from the following detailed description of an exemplary embodiment thereof, as illustrated in the accompanying drawings, in which:

FIG. 1

is a simplified schematic diagram of an ESA antenna architecture employing MEMS phase shifters in accordance with an aspect of the invention.

FIG. 2

is a simplified electrical circuit of an RF MEM switch.

FIGS. 3A-3B

are diagrammatic side views of an exemplary form of the RF MEM switch in the respective switch open (isolation) and switch closed (signal transmission) states;

FIG. 3C

is a diagrammatic top view.

FIG. 4A

illustrates a schematic of a 1 bit, hybrid switched line phase shift section employing a MEM switch.

FIGS. 4B-4D

illustrate the switch configuration in further detail.

FIG. 5

is a schematic diagram of a 4-bit phase shifter formed by four of the single bit phase shift sections of FIG.

4

.

FIGS. 6A and 6B

are respective schematic diagrams of “3.5” bit and “4.5” bit phase shifter circuits in accordance with an aspect of the invention.

FIG. 7

is an equivalent circuit diagram of an exemplary 180 degree phase shifter.

FIGS. 8A-8C

are schematic illustrations of three connections of SP2T MEM switches to realize multiple throw switching circuits.

FIGS. 8D-8I

are simplified schematic diagrams illustrating operation of the switch arrangements of

FIGS. 3A-8C

.

FIG. 9

is a simplified schematic diagram of an alternate 4-bit RF MEMS switched line phase shifter in accordance with another aspect of the invention, where the reference path in each section is replaced by a single switch.

FIG. 10

illustrates a phase shifter circuit in three sections, with SP3T junctions creating an additional transmission line path in each phase shifter section.

FIG. 11

is a schematic diagram of a reflection phase shift circuit generating phase shifts by switching in different reactances that terminate the in-phase and quadrature ports of a 3 dB quadrature hybrid coupler

FIG. 12

is a schematic diagram illustrating use of SP3T MEM switch circuits to realize a “multi-bit” reflection phase shifter section.

FIG. 13

is a schematic diagram showing RF MEMS to implement a SP3T junction providing a phase shifter termination section for the terminations for the reflection phase shifter of FIG.

12

.

FIG. 14

illustrates a single section, 2-bit reflection phase shifter employing SP3T MEM switch circuits as shown in FIG.

13

.

FIG. 15

shows an alternate 2-bit reflection phase shifter circuit employing SPST MEM switches with integrated reactance terminations.

FIG. 16

is a simplified schematic diagram of a phase shifter section realizing 0°, 22.5°, 45°, and 67.5° phase states.

FIG. 17

illustrates a reflection phase shifter employing the 2-bit reflection phase shift termination circuits of the type illustrated in FIG.

16

.

FIG. 18

is a schematic diagram of a 4-bit phase shifter with

16

phase states, using the two phase shifter sections of

FIGS. 14 and 17

.

FIG. 19

shows an exemplary MEM switch reactive termination circuit.

FIG. 20

is a schematic diagram of a reflection-type 3-bit phase shifter.

FIG. 21

illustrates a single section 3-bit phase shifter realized by a single phase section with 16 individual switch devices tied together in series.

FIG. 22

is a schematic diagram of a 5-bit phase shifter realized with two sections by using the circuits in FIG.

10

and

16

.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Space-based radar systems have a need for ESA performance for synthetic aperture radar mapping, ground moving target indication and airborne moving target indication. At the same time, the cost and weight that come with a large ESA fully populated with Transmit/Receive (T/R) modules is undesirable.

FIG. 1

is a simplified schematic diagram of an ESA

20

in accordance with an aspect of the invention, which addresses the problems of ESA cost, weight and power consumption by using an ESA antenna architecture in combination with MEMS phase shifters. The ESA in this embodiment is a one dimensional linear array of radiating elements

20

, each of which is connected to a corresponding MEMS phase shifter

30

comprising a linear array of phase shifters. The use of a linear array of the phase shifters reduces the number of transmit/receive (T/R) modules for the ESA. An RF manifold

40

combines the phase shifter RF ports into an ESA RF port. A beam steering controller

44

provides control signals to the phase shifters

30

which controls the respective phase settings of the phase shifters

30

to achieve the desired ESA beam direction.

The array

20

can include a single T/R module connected at the ESA RF port

42

, or multiple T/R modules connected at junctions in the RF manifold. The array

20

in this embodiment is capable of reciprocal (transmit or receive) operation. Moreover, a plurality of the linear arrays

20

can be assembled together to provide a two dimensional array.

The MEMS ESA provides new capabilities in such applications as space-based radar and communication systems and X-band commercial aircraft situation awareness radar. Commercial automotive radar applications including adaptive cruise control, collision avoidance/warning and automated brake application will also benefit from the MEMS ESA because this technology is scaleable to higher operational frequencies.

In the following exemplary embodiments, the MEMS phase shifters

30

employ MEM metal-metal contact switches. U.S. Pat. No. 6,046,659, the entire contents of which are incorporated herein by this reference, describes a MEM switch suitable for the purpose.

FIG. 2

is a simplified electrical circuit of an RF MEM switch

50

. The switch has RF ports

52

,

54

, and an armature

56

which can be closed to complete the circuit between the RF ports by application of a DC control voltage between line

58

and the ground

60

. The switch

50

can be fabricated with an area on the order of 0.0025 square inch, and to require less than one microwatt in DC control power, at a voltage range of 20 V to 40 V.

Unlike PIN diodes, metal-metal contact RF MEM switches do not need bias circuitry on the RF path.

FIGS. 3A-3B

are diagrammatic side views of an exemplary form of the RF MEM switch in the respective switch open (isolation) and switch closed (signal transmission) states;

FIG. 3C

is a diagrammatic top view. The drawings are not to scale. The switch

50

is fabricated on a substrate

62

, e.g. GaAs, on which are formed conductive contact layers

52

,

54

, anchor contact

64

and bias electrode

60

, conductive pads

58

,

60

, bias electrode

60

A, and traces

58

A and

60

B.

A cantilevered beam

62

fabricated as a silicon nitride/gold/silicon nitride tri-layer has an anchor end attached to contact

58

A; the opposite RF contact end is cantilevered over the RF contacts

52

,

54

, and has the armature

56

disposed transversely to the extent of the beam

58

. The armature

56

is fabricated as a gold layer in the beam, and is exposed such that when the switch is in the closed state (FIG.

3

B), the armature is brought into bridging contact between the RF contacts

52

,

54

. The beam

62

includes a conductive gold layer

62

A extending from the contact strip

58

A and over the bias electrode

60

A. The area

62

B between the armature

56

and the bias electrode is not electrically conductive, and is fabricated only of silicon nitride. Thus a DC voltage can be set up between contacts

58

,

60

, to provide a voltage between electrode

60

A and the layer

62

A in the beam, and is isolated from the armature

56

.

When the switch is open, the armature is above the RF contacts

52

,

54

by a separation distance h, which in this exemplary embodiment is 2 microns. When a DC voltage is established across the bias electrodes, the beam

62

is deflected downwardly by the electrostatic force, bringing the armature into bridging contact between the RF contacts and closing the switch. One very important aspect of the switch is the physical separation/isolation between the DC bias electrodes and the RF contacts by insulating layers, e.g. silicon nitride layers. These insulating layers isolate the DC actuation voltage from the RF line and also enhance the structural integrity and reliability of the cantilever beam

62

used in the switch. This feature simplifies the control circuit, and maintains the high RF isolation of the switch in the open state.

The metal-metal contact RF MEM switches have low insertion loss and high isolation as functions of frequency. The metal-metal contact switch is a series switch with a low capacitance in the open state that is inversely proportional to frequency. The isolation at X-band for the metal-metal contact switch is in the range of −35 to −40 dB. Also the isolation performance of the metal-metal contact switch improves with decreasing frequency making it suitable for point to point radio applications.

In accordance with an aspect of the invention, a new class of switched line phase shifter configurations using RF MEM switches is provided.

FIG. 4A

illustrates a schematic of a 1 bit, hybrid switched line phase shift section

100

, or “unit cell.” Like conventional PIN diode and FET switched phase shifters, the phase shifter is realized by switching in different lengths of transmission lines (FIG.

4

). Unlike PIN diode and FET switches, DC bias used to actuate the metal-metal RF MEMS switches is not coupled to the RF transmission line. This embodiment of the unit cell is fabricated on a low-loss substrate

102

, e.g. alumina. A conductor pattern is fabricated on the top surface of the substrate to define the RF ports

104

,

106

, and the reference transmission line path

108

and phase shift transmission line path

110

. The MEM switch

50

A is connected by wire bond connections

112

,

114

between the port

104

and one end of the reference path

108

. Elements of the switch

50

A are diagrammatically shown in

FIG. 4

, including the RF ports indicated as

50

A-

1

and

50

A-

2

to which the wire bond connections are made. The cantilever beam is shown as element

50

A-

3

. The DC bias connections are made at

50

A-

4

and

50

A-

5

. The other end of the reference path

108

is connected though switch

50

B to the RF port

106

.

MEM switch

50

C is connected via wire bonds between the port

104

and an end of the phase shift path

110

. Switch

50

D is connected between the other end of the phase shift path and the port

106

. It can be seen that by appropriate control of the MEM switches, either (or both) paths

108

,

110

can be connected between the ports

104

,

106

.

FIG. 4B

illustrates an arrangement of MEMS devices used for the switched line phase shifter of

FIG. 4

, with MEMS device A representing MEM switch

50

A, and MEMS device B representing MEM switch

50

C of FIG.

4

A. The equivalent circuit for this arrangement is provided by SPST switches A, B, (FIG.

4

C). The arrangement of MEMS A and B provides two states, a first state with switch A open and switch B closed, and a second state with switch A closed and switch B open.

FIG. 4D

shows the equivalent SP2T switch providing these two states.

The basic single bit RF MEMS switched line phase shifter

100

shown in

FIG. 4A

uses a SP2T junction. Four of these single bit unit cell can be combined to form a 4-bit phase shifter

120

as shown in FIG.

5

. Thus, single bit unit cells

100

A,

100

B,

100

C and

100

D, each with a different phase shift transmission path length, are connected in series to form a four bit shifter. For this embodiment, the unit cells are mounted on a substrate

124

, e.g. alumina, in close series proximity so that wire bond connections

122

A,

122

B and

122

C can be used to make RF connections between adjacent RF ports of the unit cells. Unit cell

100

A has the length of phase shift path

100

A-

1

selected to provide 180° phase shift at an operating wavelength. The respective phase shift paths

100

B-

1

,

100

C-

1

and

100

D-

1

are selected to provide respective phase shifts of 90°, 45° and 22.5°.

Further advancement of the single bit RF MEMS switched line phase shifter is achieved by using a SP3T junction to realize an additional transmission line path while maintaining the same foot print of the basic single bit circuit. While the basic single bit switched line phase shifter circuit or unit cell

100

(

FIG. 4A

) has only one phase shift state, a MEMS circuit using a SP3T junction has two phase shift states. This RF MEM switched line phase shifter section is combined to realize the equivalent “3.5” bit and “4.5” bit phase shifter circuits shown in

FIGS. 6A and 6B

. The “3.5” bit phase shifter circuit

140

has nine phase states, i.e. approximately 3.5 bits, and the loss through the circuit is largely determined by the cumulative loss of MEM switches

142

A,

142

B,

144

A,

144

B. Each of these m~q switches is a SP3T switch. The circuit

140

includes two sections or cells

142

,

144

. Cell

142

includes MEM switches

142

A,

142

B, a reference signal path

142

C, and two phase shift paths

142

D,

142

E of unequal length. Section

144

includes MEM switches

144

A,

144

B, reference signal path

144

C, and two phase shift paths

144

D,

144

E of unequal length. The circuit RF ports

146

,

148

are connected to one side of the respective switches

142

A,

144

B. Switches

142

A,

142

B provide the capability of selecting the reference path

142

C, phase shift path

142

D or phase shift path

142

E. Switches

144

A,

144

B provide the capability of selecting the reference path

144

C, phase shift path

144

D or phase shift path

144

E. A connection path

145

connecting switches

142

B and

144

A.

FIG. 6B

shows a “4.5” bit phase shifter

150

using SP3T switch circuits. This circuit has three sections

152

,

154

,

156

, instead of two sections as in the circuit

140

. Each section has two SP3T MEM switches to select a reference path, a first phase shift path or a second phase shift path. The sections are connected in series.

As shown in Table 1, the “4.5” bit phase shifter

150

has 27 phase shift states while the basic 4-bit phase shifter (

FIG. 5

) has 16 phase shift states. Moreover, the “4.5” bit phase shifter

150

uses only three sections while the basic 4-bit phase shifter uses four sections. Thus the “4.5” bit phase shifter

150

(

FIG. 6B

) will have less RF loss than the basic 4-bit phase shifter (

FIG. 5

) and will offer more phase shift states than the basic 4-bit phase shifter. When the “4.5” bit phase shifter is installed into the MEMS ESA architecture (FIG.

1

), the ESA will have more fixed beam positions without sacrificing gain.

TABLE 1

Phase

States

“3.5”-Bits

4-Bits

“4.5”-Bits

1

0

0

0

2

40

22.5

13.3333333

3

80

45

26.6666667

4

120

67.5

40

5

160

90

53.3333333

6

200

112.5

66.6666667

7

240

135

80

8

280

157.5

93.3333333

9

320

180

106.666667

10

202.5

120

11

225

133.333333

12

247.5

146.666667

13

270

160

14

292.5

173.333333

15

315

186.666667

16

337.5

200

17

213.333333

18

226.666667

19

240

20

253.333333

21

266.666667

22

280

23

293.333333

24

306.666667

25

320

26

333.333333

27

346.666667

The high isolation provided by the RF MEMS switches allow the transmission lines in a switched line phase shifter to be compacted closer together without penalty of RF performance degradation. The reference path of the basic switched phase shifter section shown in

FIG. 4A

includes two SPST switches and a length of transmission line. By compacting the footprint of each phase shifter section, the reference path in each section can be reduced to a single RF MEMS switch as shown in the equivalent circuit diagram of an exemplary 180 degree phase shifter

170

in FIG.

7

. Further compaction would reduce the discrete MEMS switch combination into an integrated MMIC as shown in

FIGS. 8A-8C

.

The phase shifter

170

illustrated in

FIG.7

includes three SPST MEM switches

176

A-

176

C. The RF ports

172

,

174

are connected to the switch

176

A by wire bond connections illustrated as inductances in FIG.

7

. The switch

176

A forms the reference path for the phase shifter

170

. A 180° phase shift path

178

is selectively coupled to the RF ports

172

,

174

by MEM switches

176

B,

176

C. In an exemplary embodiment, the circuit is fabricated on an alumina substrate, and path

178

is formed by a microstrip line on the substrate. Wire bond connections represented by inductances connect the switches

176

B,

176

C to nodes

180

A,

180

B. The values of the capacitances and the inductances (wire bond lengths) are designed to match the common junction impedances in a manner well known in the art.

The low capacitance of the metal-metal contact switches in the open state results in low parasitics at the switch junctions, as well as high isolation. Low parasitics make it possible for multiple metal-metal contact switches to share a common junction in parallel, i.e., the low parasitics enable the realization of MEM single-pole multi-thrown switch junctions. These “junctions” can be realized in hybrid circuits or integrated as a single MMIC chip.

FIGS. 8A-8I

illustrate various new arrangements of MEM RF switches, e.g. metal-metal contact RP MEMS series switches. While the basic MEMS switch is a SPST device, these switch arrangements provide aspects of the invention, and can be employed not only in phase shifters, but in other applications including switchable attenuators, switchable filter banks, switchable time delay lines, switch matrices and transmit/receive RF switches. These arrangements can be realized as discrete MEMS devices in a hybrid microwave integrated circuit (MIC) or as a single monolithic microwave integrated circuit (MMIC) device.

FIGS. 8A-8C

illustrates the “single-pole 2-throw” (“SP2T”) junction and “single-pole 3-throw” (“SP3T”) junctions as MMIC chips. The DC control lines for the switch junctions pass through vias.

FIG. 8A

shows an arrangement of MEMS devices A, B and C, as used for a switched line phase shifter, described below with respect to FIG.

9

.

FIG. 8B

shows an arrangement of MEMS devices A, B and C, as used for a multi-bit reflection phase shifter described below with respect to

FIGS. 13 and 19

.

FIG. 8C

shows an arrangement of MEMS devices (

1

-

5

) as used for a multi-bit switched line phase shifter described more fully below with respect to FIG.

10

.

FIG. 8D

shows the equivalent circuit for the switch arrangement of

FIG. 8A

, including three SPST switches A, B and C, which is capable of eight switch positions. Table 2 show the switch positions used to create the two phase states in the switched line phase shifter of FIG.

9

. An alternative equivalent circuit is shown in

FIG. 8E

, which provides the same switch positions as a combination of a SP2T switch A-B and a SPST switch C.

TABLE 2

Switch

Switch

Switch

State

A

B

C

1

OPEN

CLOSE

OPEN

2

CLOSE

OPEN

CLOSE

FIG. 8F

shows an equivalent circuit for the switch arrangement of

FIG. 8B

, including three SPST switches A, B, C, which together are capable of eight switch positions as shown in Table 3. Table 3 show the switch positions (associated with the combination of three SPST switches) used to create the eight phase states in the multi-bit reflection phase shifter circuit

400

of FIG.

19

.

TABLE 3

Switch

Switch

Switch

State

A

B

C

1

OPEN

OPEN

OPEN

2

OPEN

OPEN

CLOSE

3

OPEN

CLOSE

OPEN

4

OPEN

CLOSE

CLOSE

5

CLOSE

OPEN

OPEN

6

CLOSE

OPEN

CLOSE

7

CLOSE

CLOSE

OPEN

8

CLOSE

CLOSE

CLOSE

A subset of the switch positions in Table 3 is shown in Table 4. The switch positions in Table 4 can be used to create the four phase states in the multi-bit reflection phase shifter circuit

250

of FIG.

13

. While using the same MEMS arrangement in FIG.

8

B and switch positions in Table 4, the equivalent circuit in

FIG. 8D

reduce to that of a “SP3T” as illustrated in FIG.

8

G. (Note the “SP3T” switch described in Table 4 is really a SP4T with one of the output ports terminated to an open circuit.)

TABLE 4

Switch

Switch

Switch

State

A

B

C

1′

OPEN

OPEN

OPEN

2′

OPEN

OPEN

CLOSE

3′

OPEN

CLOSE

OPEN

4′

CLOSE

OPEN

OPEN

FIG. 8H

shows an equivalent circuit for the switch arrangement of

FIG. 8C

, including five SPST switches (

1

-

5

) which together are capable of

120

switch positions. Table 5 show the switch positions used to create the three phase states in the switched line phase shifter of FIG.

10

. Note the switch positions are the same as a combination of SP3T and SPST switches shown in FIG.

8

I.

TABLE 5

Switch

Switch

Switch

Switch

Switch

State

1

2

3

4

5

1

OPEN

OPEN

OPEN

OPEN

OPEN

2

OPEN

OPEN

CLOSE

CLOSE

OPEN

3

CLOSE

CLOSE

OPEN

OPEN

OPEN

Table 6 shows the MEM switch positions and their respective phase shifts for the 5-Bit phase shifter network (

FIG. 22

) including circuits

250

(

FIG. 13

) and

400

(FIG.

19

). In this table, the MEMS switch is identified by their associated phase shift. The open switch position is designated by “0” while the closed switch is designated by “1”. Note that multiple switches are closed for some phase state indicating that their associated termination are being added in parallel. The switch positions associated with circuit

250

is indicative of a SP3T switch while the switch positions are associated with circuit

400

is indicative of a 3P3T switch.

TABLE 6

MEMS Switch Position

Phase

Phase

270

180

90

45

22.5

11.3

Bit

Shift

State

0

0

0

0

0

0

00000

0

1

0

0

0

0

0

1

00001

11.25

2

0

0

0

0

1

0

00010

22.5

3

0

0

0

0

1

1

00011

33.75

4

0

0

0

1

0

0

00100

45

5

0

0

0

1

0

1

00101

56.25

6

0

0

0

1

1

0

00110

67.5

7

0

0

0

1

1

1

00111

78.75

8

0

0

1

0

0

0

01000

90

9

0

0

1

0

0

1

01001

101.25

10

0

0

1

0

1

0

01010

112.5

11

0

0

1

0

1

1

01011

123.75

12

0

0

1

1

0

0

01100

135

13

0

0

1

1

0

1

01101

146.25

14

0

0

1

1

1

0

01110

157.5

15

0

0

1

1

1

1

01111

168.75

16

0

1

0

0

0

0

10000

180

17

0

1

0

0

0

1

10001

191.25

18

0

1

0

0

1

0

10010

202.5

19

0

1

0

0

1

1

10011

213.75

20

0

1

0

1

0

0

10100

225

21

0

1

0

1

0

1

10101

236.25

22

0

1

0

1

1

0

10110

247.5

23

0

1

0

1

1

1

10111

258.75

24

1

0

0

0

0

0

11000

270

25

1

0

0

0

0

1

11001

281.25

26

1

0

0

0

1

0

11010

292.5

27

1

0

0

0

1

1

11011

303.75

28

1

0

0

1

0

0

11100

315

29

1

0

0

1

0

1

11101

326.25

30

1

0

0

1

1

0

11110

337.5

31

1

0

0

1

1

1

11111

348.75

32

It is an important feature that two or more MEMS can be combined at a single junction to form single-pole-multi-throw (SPMT) or multi-pole-multi-throw (MPMT) switch circuits, as illustrated in

FIGS. 8A-8I

. This feature is facilitated by the fact that the DC control signals are isolated from the RF signal path through the MEMS.

Applying this innovation to the basic 4-bit RF MEMS switched line phase shifter in

FIG. 5

results in realization of the alternate embodiment of

FIG. 9

, where the reference path in each section is replaced by a single switch. The 4-bit circuit

200

of

FIG. 9

has less RF loss and uses fewer switches than the 4-bit phase shift circuit of FIG.

5

.

The phase shifter

200

has RF ports

202

,

204

, and four sections

206

,

208

,

210

,

212

. Each section is identical except the electrical length of the respective phase shift path. Thus, section

206

includes SPST MEM switch

206

A connected between the section RF terminals

206

B,

206

C, to provide the reference path. The phase shift path

206

D is provided by a transmission line segment, e.g. microstrip, which is selected by SPST MEM switches

206

E,

206

F. The SPST switches

206

A and

206

E form a SP2T switch circuit. The phase shift paths for the different sections have different electrical lengths to provide the desired phase shifts for the particular sections. For the case of microstrip phase shift paths, the microstrip lines can be fabricated off-chip, with the MEMS in each section fabricated on a single chip or substrate, or alternatively on separate chips or substrates. The four sections are connected in series, to provide a 4-bit phase shifter having 16 phase states.

Further advancement is achieved when the SP2T junction switches used in the circuit of

FIG. 9

are replaced with SP3T junctions to create an additional transmission line path in each phase shifter section. The resulting phase shifter circuit

230

shown in

FIG. 10

has 18 phase states using 13 switches in three sections, while the 4-bit circuit in

FIG. 9

has 16 phase states using 12 SPST switches. The basic 4-bit RF MEMS switched line phase shifter in

FIG. 5

has

16

phase states using

16

SPST switches. Thus, metal-metal contact series switches enable single-pole multi-throw junctions, which in turn make it possible to realize phase shifters with fewer switches, and hence lower insertion loss and reduced cost.

The phase shifter

230

includes RF ports

232

and

234

, connected by the three phase shift sections

236

,

238

and

240

. Section

236

includes a first SPST MEM switch

236

A which is connected between the section RF terminals

236

B,

236

C to provide the reference path. This section has two phase shift paths

236

F,

236

I, provided by respective transmission lines, of respective electrical lengths 120° and 240°. The 240° path

236

F is selected by SPST MEM switches

236

D,

236

E. The 120° path

236

I is selected by SPST MEM switches

236

G,

236

H. The three SPST MEMS

236

A,

236

D,

236

G form a SP3T switch circuit.

Section

238

has three states as well, 0°, 40° and 80°. The reference path (0°) is provided by SPST MEM switch which connects the section RF terminals

238

B,

238

C. This section has two phase shift paths

238

F,

238

I, provided by respective transmission lines, of respective electrical lengths 40° and 80°. The 40° path

236

F is selected by SPST MEM switches

238

D,

238

E. The 80° path

238

I is selected by SPST MEM switches

238

G,

238

H.

The section

240

has two states, 0° and 20°. The reference (0°) path is provided by SPST MEM switch connecting the section RF terminals

240

B,

240

C. The 20° phase shift path

240

D is provided by a transmission line selectively switched by SPST switches

240

E,

240

F.

Another aspect of the invention is a new class of reflection phase shifter configurations that employs metal-metal RF MEMS switches.

FIG. 11

is a schematic diagram of a reflection phase shift circuit

200

. Like conventional PIN diode and FET reflection phase shifters, the circuit generates phase shifts by switching in different reactances that terminate the in-phase and quadrature ports

202

C,

202

D of a 3 dB quadrature hybrid coupler

202

. Each of reactant terminations

208

,

210

generates a complex reflection coefficient close to unity in magnitude but with different phase angles. The reactances can be fabricated with inductances, capacitances, inductances and capacitances, or by transmission line segments. In this embodiment, the reactances

208

,

210

are equal reactances, and the switches

204

and

206

are operated in tandem, both open or both closed, to provide symmetrical operation. The RF input is at port

202

A; the phase shifter RF output is at port

202

B. The switches

204

,

206

are RF MEM switches, as illustrated in

FIGS. 2 and 3

. The phase shift is given by:

ΔΦ

n

=−2[tan

1

(B)δ

1n

]

where n=0, 1, δ=Kronecker delta function=1 (switch open), 0 (switch closed).

Unlike PIN diode and FET switches, DC bias used to actuate the metal-metal RF MEMS switches is not coupled to the RF transmission line. This embodiment of a reflection phase shifter has only two phase states (one-bit) per unit cell or section; this is also the case of a conventional reflection phase shifter using PIN diode or FET switches.

In reflection phase shifter configurations, the MEM switches are able to combine the termination reactances in parallel. Thus the functionality of a 3-bit phase shifter (including three sections) can be combined in a single section. These new circuits occupy the same foot print as a conventional single bit phase shifter circuits but have increased capability to generate twice or more the number of phase shift bits than the convention designs with less RF loss across a wide band width.

The use of a new single pole multi-throw junction in a reflection phase shifter thus provides another new reflection phase shifter configuration. This is realizable because of the RF characteristics exhibited by the metal-metal contact RF MEMS switch. By using a single phase shifter “section” or unit cell, multiple phase states can be realized by switching in the different reactances that terminate the coupler. The use of diode (PIN or varactor) and FET switch is not appropriate for this configuration because of the higher RF losses associated with these devices and because of the performance limitation due to the required bias circuitry along the RF path.

FIG. 12

is a schematic diagram illustrating use of SP3T MEM switch circuits to realize a “multi-bit reflection phase shifter section”. In this embodiment, the SPST switches of the embodiment of

FIG. 11

are replaced with SP3T MEM switch circuits

224

,

226

, each fabricated by use of three SPST switches as illustrated in FIG.

8

B. The SP3T circuits can be fabricated by bonding three SPST MEM switch chips to a common junction, or by combining three SPST MEM switches with a common junction on a single substrate or chip. The respective ports

224

A,

224

B,

224

C are coupled to corresponding normalized reactances

228

A,

228

B,

228

C, to provide a means to select the termination reactance. The phase shift ΔΦ

xyz

provided by the circuit

220

is given by:

ΔΦ

xyz

=−2[tan

−1

(A)*x+tan

−1

(B)*y+tan

−1

(C)*z]

where x=1 when port

224

A is open, and=0 when closed; y=1 when port

224

B is open and=0 when closed; z =1 when port

224

C is open and=0 when closed. The switches

224

and

226

are operated in tandem, so that reactances

228

A and

230

A are selected together, or reactances

228

A,

230

C are selected together, or reactances

228

C,

230

C are selected together, or both switches are open.

The approach of using RF MEMS to implement a SP3T junction is applied to provide a phase shifter termination section

250

, illustrated in

FIG. 13

, providing the 0°, 90°, 180°, and 270° phase states for the terminations for the reflection phase shifter

220

of FIG.

12

. The circuit

250

can be fabricated as a monolithic or hybrid device, and comprises an RF port

252

to which the SPST MEM switches

254

,

256

,

258

are connected. The MEM switch

254

couples the node

252

to capacitor

260

and ground. The MEM switch

256

couples the node

252

to inductor

262

and ground. The MEM switch

258

couples the node

252

to inductor

264

and ground.

In operation, all MEM switches

254

,

256

,

258

are open to provide the reference phase (0°). For 90°, MEMS

254

is closed, and MEMS.

256

,

258

are open. For 180°, MEMS

256

is closed, and MEMS

254

and

258

are open. For 270°, MEMS

258

is closed, and MEMS

254

and

256

are closed. The reactance values for capacitor

260

and inductors

262

and

264

are selected to provide the respective desired phase shifts.

In an exemplary embodiment, the phase shifter section

250

can be fabricated to operate across the wide 8 GHz to 12 GHz frequency band.

FIG. 14

illustrates a single section, 2-bit reflection phase shifter

270

employing SP3T MEM switch circuits as shown in FIG.

13

. The phase shifter has RF ports

272

,

274

, at the RF ports of the 3 dB hybrid coupler

276

. The SP3T MEM switch circuits

250

-

1

and

250

-

2

are connected at the in-phase and quadrature ports of the coupler

256

:. In this embodiment, the reactance terminations are integrated into the MEM switch circuits. The four phase states are provid- ed by operating the MEMS

250

-

1

,

250

-

2

in tandem, to select symmetrical reactances in the respective MEMS. Thus, the reference phase state is provided with all MEMS are open, and the three phase shift states are provided by closing corresponding ones of the SPST MEM switches which together comprise the respective SP3T switch circuits

250

-

1

,

250

-

2

.

FIG. 15

shows an alternate 2-bit reflection phase shifter circuit

300

employing SPST MEM switches with integrated reactance terminations. This configuration employs two single bit sections

200

-

1

and

200

-

2

connected in series. The sections

200

-

1

and

200

-

2

are of the type illustrated in FIG.

11

.

A phase shifter section

320

designed to realize the 0°, 22.5°, 45°, and 67.5° phase states is shown in FIG.

16

. This phase shifter section can be fabricated to operate across a wide 8 GHz to 12 GHz frequency band. The circuit

320

can be fabricated as a monolithic or hybrid device, comprising an RF port

322

to which the SPST MEM switches

330

,

332

,

334

are connected. The MEM switch

324

couples the node

322

to capacitor

330

and ground. The MEM switch

326

couples the node

322

to inductor

332

and ground. The MEM switch

328

couples the node

322

to inductor

334

and w ground. This phase shifter section is operated in a similar manner to that described with respect to circuit

250

of

FIG. 13

; however, the reactance values will be selected to provide the 22.5°, 45°, and 67.5° phase states.

FIG. 17

illustrates a reflection phase shifter

350

employing the 2-bit reflection phase shift termination circuits of the type illustrated in

FIG. 16

as circuit

320

. The phase shifter

350

has RF ports

352

,

354

and a quadrature coupler

356

. The 2-bit reflection devices

320

-

1

and

320

-

2

are connected to the in-phase and quadrature sidearm ports of the coupler

356

. The SP3T switch circuits

320

-

1

and

320

-

2

are operated in tandem, employing corresponding reactance values for the terminations to provide balanced operation.

The two phase shifter sections of

FIGS. 14 and 17

combine to form the equivalent of a 4-bit phase shifter with 16 phase states (FIG.

18

). Thus, phase shift circuit

380

has RF ports

382

and

384

. Two quadrature hybrid. couplers

386

,

388

are connected in series, with RF output port

386

B of coupler

386

coupled to RF input port

388

A of coupler

388

. SP3T MEM switch circuits

250

-

1

and

250

-

2

with integrated reactive terminations (as shown in

FIG. 13

) are connected to the in-phase and quadrature sidearm ports of the coupler

386

. With the first section (including coupler

386

) providing phase shift states of 0°, 90°, 180° and 270°, and with the second section (including coupler

388

) providing phase shift states of 0°, 22.5°, 45° and 67.5°, the phase shifter

380

can provide 16 phase shift states.

The phase shifter sections described above with respect to

FIGS. 14 and 17

actuates the SPST MEM switches within each SP3T junction one at a time. Further advances can be achieved when multiple switches are actuated simultaneously and their corresponding reactant terminations are added together in parallel. The new impedances resulting from these parallel combinations of reactances realize additional phase states. Again this is possible because of the high isolation and low RF loss generated by the metal-metal contact RF MEMS switches.

FIGS. 19 and 20

illustrates a circuit designed to create phase states using the parallel combination of the baseline terminations when actuating multiple switches simultaneously.

FIG. 20

is a schematic diagram of a reflection-type 3-bit phase shifter

420

, having RF ports

422

and

424

, and a hybrid 3 dB coupler

426

having in-phase and quadrature ports

426

A,

426

B. Respective MEM switch reactive termination circuits

400

-

1

and

400

-

2

with a 3P3T junction are used to terminate the coupler ports

426

A,

426

B.

FIG. 19

shows an exemplary MEM switch reactive termination circuit

400

as used in the circuit of FIG.

20

. It is possible to realize as many as eight phase states from a junction

402

with three SPST MEM switches

404

,

406

,

408

respectively connecting to reactances

410

,

412

,

414

, to realize a 3-bit phase shifter. This single section 3-bit phase shifter circuit equates the phase shift performance of three conventional single bit phase shifter sections using

6

individual PIN diode switch devices. The circuit

420

employs identical circuits

400

-

1

and

400

-

2

in a balanced configuration.

A single section 3-bit phase shifter can also be realized by a single phase section with 16 individual switch devices tied together in series (FIG.

21

). This is shown in

FIG. 21

, in which phase shifter

440

includes RF ports

442

,

444

, and a 3 dB hybrid coupler

446

. The in-phase and quadrature ports

446

A,

446

B are terminated by respective series circuits

450

,

452

. Each series circuit including alternating series connected transmission line segments, e.g. segment

450

B and MEM SPST switches, e.g. switch

450

A. The phase shift then becomes the cumulative round trip time delay of the transmission line segments when they are switched together in series. The cumulative delay is selected by the appropriate control of the MEM switches to lengthen/shorten the round trip path length

FIG. 22

is a schematic diagram of a 5-bit phase shifter

460

realized using two sections

462

,

464

by using the circuits in

FIG. 10 and 16

. Thus, section

462

includes a hybrid 3 dB coupler with SP3T MEM switch reactance terminations

250

-

1

and

250

-

2

connected to the in-phase and quadrature ports. Section

464

is connected in series to section

462

, and includes coupler

464

A with 3P3T MEM switch reactance terminations

400

-

1

and

400

-

2

. This new phase shifter uses four SP3T junctions and generates 32 phase states using only two sections. Thus, metal-metal contact series switches enable single-pole multi-throw junctions, which in turn make it possible to realize phase shifters with fewer switches, and hence lower insertion loss and reduced cost.

The phase shifter circuits in accordance with this invention have many advantages, including advantages resulting from the MEM switches. MEM RF switches do not require any DC biasing circuit along the RF path. A single MEM RF switch has better wide band RF performance than a comparable but more complex design using multiple PIN diodes and FET devices. A phase shifter circuit using MEM RF switches can then operate across a wider frequency band with lower RF loss, higher 3rd order intercept point and higher isolation than what has been achieved with current state of the art devices. This is done without sacrificing weight, cost or power consumption. Low cost manufacturing of MEMS is achieved using standard thin film fabrications processes and materials use in the commercial IC industry. Unlike conventional IC devices, MEMS RF switches can also be fabricated directly onto ceramic hybrid circuit and traditional printed circuit board assemblies to achieve even lower cost.

The use of MEMS RF switches results in the realization of phase shifter circuits that operate across a wider frequency band, with lower RF, higher 3rd order intercepts point and less DC power consumption than what is available in currently used state of the art devices (or circuits). The unique construction of the metal to metal contact MEMS RF switch allows it to operate as a series switch. Because DC actuation of metal-to-metal contact MEMS RF switches is decoupled from the RF path, these switches do not require any DC biasing circuits along the RF path. Thus, these series switches can be combined to form multi-pole, multi-throw switches (FIGS.

8

A-BC) and can be used to realize multi-phase switched line phase shifter circuits. These circuits occupy the same foot print as a convention single bit phase shifter circuits but have increased capability to generate twice the number phase shift bits than the convention designs with less RF losses across a wide band width.

It is understood that the above-described embodiments are merely illustrative of the possible specific embodiments which may represent principles of the present invention. Other arrangements may readily be devised in accordance with these principles by those skilled in the art without departing from the scope and spirit of the invention.

Number	Name	Date	Kind
4751453	Foti	Jun 1988	A
4764740	Meyer	Aug 1988	A
5379007	Nakahara	Jan 1995	A
5757319	Loo et al.	May 1998	A
6046659	Loo et al.	Apr 2000	A
6281838	Hong	Aug 2001	B1

Multi-bit phase shifters using MEM RF switches

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

Government Interests

US Referenced Citations (6)