DE102008023374A1 - Filter circuit, has reactance element electrically switched between connections, and base switching elements electrically switched over inputs and outputs in signal path in parallel manner - Google Patents

Abstract

The circuit has a signal path (SP) connecting signal path inputs (SPE) with signal path outputs (SPA). Each of a set of ground connection (MA) has a base switching element (BSE1, BSE2). A series resonator i.e. surface acoustic wave resonator, and parallel resonators are switched between the inputs and the outputs, the inputs and the connections, and the connections and the outputs, respectively. A reactance element is electrically switched between the connections. The switching elements are electrically switched over inputs and outputs in the path in a parallel manner. An independent claim is also included for a method for optimizing a filter circuit.

Description

The The invention relates to a filter circuit in ladder type-like Structure with improved insulation or improved insertion loss and a method for optimizing the filter circuit.

From the publication DE 102 006 005 298 A is a duplexer with high isolation in the receiving band known. In the Rx filter, two shunt branches of a ladder-type structure of SAW resonators are connected in parallel and connected in series with an inductance. By adapted inductances and capacitances it is achieved that a received signal is reflected by the output of the transmit filter and conducted into the receive path; the transmission filter acts as a band-stop filter for received signals.

From the patent EP 0 995 265 B1 is a surface wave filter in Laddertype arrangement with improved edge steepness known. The improved edge steepness of the passband is achieved in that the Finger¬periodi¬zitäten of parallel or serial resonators are slightly different from each other.

From the patent EP 1 196 991 B1 For example, a surface acoustic wave filter of the reactance type with improved stopband suppression is known. Special designs of ladder-type structures allow the shifting of poles of the transfer function to lower frequencies.

From the publication DE 199 32 649 A1 is a SAW filter ladder-type-like structure known.

One A problem of the prior art is that known filters due to the ever increasing demands on the filter characteristics z. B. in frequency bands used by mobile communication devices no longer meet the new specifications.

task the present invention is to provide a filter circuit, the improved damping characteristics and a larger Has variability in the positioning of poles.

These The object is achieved by a filter circuit solved according to claim 1. Advantageous embodiments result from the dependent claims.

The The invention comprises a signal path with a signal path input and a signal path output and two basic circuit elements connected serially in Signal path are interconnected. Each of the two basic circuit elements has three resonators and one reactance element. One of the resonators, a so-called series resonator is connected in the signal path. A second resonator (a first parallel resonator) is connected to a Connected electrode at the signal input of the base circuit element, while a third resonator (a second parallel resonator) with an electrode at the signal output of the base circuit element is interconnected. The respective other electrode of the parallel resonators are electrically connected to each other via a connecting line connected. This connection line is via a reactance element connected to ground. Such a basic circuit element in the signal path the filter circuit acts as a bandpass filter.

In order to a filter according to the invention has a ladder type-like Structure on. Filter circuits with ladder-type structure are off constructed in series connected basic elements, consisting essentially of a resonator in a "series branch" and a Resonator in a "parallel branch" exist. The characteristic "passage frequency" of the series resonator agrees approximately with the "blocking frequency" of Parallel resonator match. This forms such a basic element a passband filter for itself. The right flank of the damping characteristic of Passbands will be decisive for the concrete design of the series resonator, while the left flank decisive for the design of the parallel resonator is determined. Ladder type filter circuits from such basic elements are well known.

As expected in the described basic circuit element two poles of the Insertion loss at the left flank, if the two resonance frequencies of both parallel resonators are slightly different differ from each other. Because at these frequencies flows a signal from the signal path either via the first parallel resonator or via the second parallel resonator and each over the reactance element from ground. In an inventive Filter circuit, however, shows an additional third Pole on the left flank, whose position depends on the reactance of the Reaktanzelements depends.

This Effect is called "groundloop effect". By the "groundloop effect" becomes the passband, the through the two basic elements and the choice of series and parallel resonators is determined, not impaired. Rather, the allowed Change in the reactance of the reactance element a freely selectable Positioning of the additional third pole. In the result one obtains an improved variability in the Design of the insertion loss in the stopband, without compromising the quality of the damping characteristic in the remaining area (eg in the passband) is negatively influenced.

The Inventive series connection of two Base circuit elements can therefore be four poles, their location relatively fix, lead while two more Poles in a certain frame according to the dimensioning the respective reactance elements can be positioned.

The two in the position of the frequencies variable poles can an optimization of the insertion loss accordingly offer a stricter specification, as provided by the previous one State of the art is not possible.

Further Embodiments consist of further "series resonators" in the Signal path or further "parallel resonators" in to interconnect further parallel paths (parallel branches). Latter You can use it to create more poles by sending signals derive from the signal path via ground.

The Reactance elements may have different impedances.

Especially It is advantageous to use the resonators as SAW or BAW resonators train. These resonators working with acoustic waves have in the static case (ie at frequencies significantly different from distinguish between the acoustic resonance and anti-resonance frequencies) a so-called "static capacity" C0, while in the dynamic case (i.e., acoustic case in the vicinity of the resonance and anti-resonance frequencies) so-called dynamic capacity C1 have. Both capacities are proportional to each other. This results in another advantage the filter circuit according to the invention: An optimization the static capacity C0 in favor of a given Range of insertion loss outside of the passband causes due to the said proportionality a change in a ladder type structure filter the dynamic capacity C1 and thus usually a deterioration the filter characteristic in the passband. By the invention Interconnection receives the designer of the circuit another Degree of freedom for optimization, without a deterioration of the damping characteristic in other frequency ranges.

Further advantageous embodiments are the resonators as SAW resonators on lithium tantalate or lithium niobate as substrate material form or arrange as BAW resonators on a silicon chip.

The electrical connection lines of the base circuit elements can be structured as electrical traces on the chip. One Chip, the corresponding resonators working with acoustic waves can be used on a multilayer substrate which has an integrated Wiring may be arranged. Furthermore can in the multilayer substrate passive components the filter circuit, for example, matching elements and the aforementioned Reaktanzelemente be integrated.

The described filter circuit can additional filter elements, such as B. DMS (Dual Mode SAW) filter, which in series with can be connected to the signal path.

Especially advantageous applications of the filter circuit consist in that the filter is used as part of a bandpass filter can be. The bandpass filter in turn can be part of a duplexer be.

at The filter circuit can be used as part of a duplexer at substantially unchanged insertion loss have improved isolation in the passband. The filter circuit can even with substantially unchanged insulation an improved Have insertion loss in the pass band.

One Method of optimization is to provide a filter circuit, which has a conventional ladder-type structure with four parallel paths. Parallel resonators and series resonators are used their properties and in particular their resonance frequency out optimized to a desired bandpass filter characteristic. In The next step will be two of the four parallel paths massively connected to each other and each have one in common used reactance element connected to ground. It is due to the Groundloop effect one extra pole in each Created near the left flank of the passband. These Poles will now pass through according to the intended application Variation of the reactance elements to the desired frequency positions postponed.

The two reactance elements may be inductors. The inductors can be different from each other and preferably in the range between 0.5 nH and 2 nH.

in the Below is the filter circuit based on embodiments and associated schematic figures explained in more detail. Show it:

1a a basic element of a ladder-type structure,

1b a typical damping characteristic of a passband filter,

1c a conventional ladder type pe structure

2 a ladder-type-like structure with two basic circuit elements according to the invention,

3 a basic circuit element,

4 an advantageous filter circuit in ladder-type-like structure,

5 a filter circuit in ladder-type-like structure with advantageous additional resonators and reactance elements,

6a an insertion loss characteristic of a duplexer,

6b the frequency-dependent isolation of a duplexer.

1a shows a basic element of a ladder type circuit. A series resonator SR is connected in a signal path SP and a parallel resonator PR is connected in a parallel path PP. The parallel resonator is electrically connected on the one hand to the signal path and on the other hand to ground MA.

The 1b shows a typical insertion loss of a basic element of 1a , Plotted is the attenuation (in dB) versus frequency (in MHz). Poles exist at frp, the resonant frequency of the parallel resonator PR and at fas, the anti-resonant frequency of the series resonator SR. The pass band is formed in the range of frequencies frs and fap, which corresponds to the resonance frequency of the series resonator or the antiresonance frequency of the parallel resonator.

The 1c shows a ladder-type structure that serves as the basis of the present invention. Two series resonators SR1 and SR2 are connected in a signal path SP and four parallel resonators PR11, PR21, PR12 and PR22 are connected in four parallel paths PP11, PP21, PP12 and PP22. The parallel paths are electrically connected on the one hand to the signal path and on the other hand to ground.

2 shows two inventive basic circuit units BSE1 and BSE2, which are connected in a signal path SP in series. Accordingly, the signal input of the second base circuit element is connected to the signal output of the first base circuit element. The signal path has a signal path input SPE and a signal path output SPA. Each of the two base circuit elements BSE1 and BSE2 is connected to ground MA via a reactance element.

3 shows a detailed described basic circuit element BSE. The base circuit element comprises a signal input SE and a signal output SA. In between, a series resonator SR is interconnected. A first parallel resonator PR1 is connected to the signal input SE and a second parallel resonator PR2 is connected to the signal output SA. On the ground side, both parallel resonators PR1 and PR2 are connected via an electrically conductive connecting line VL and connected to ground via a reactance element, which is connected to a connecting terminal VA on the connecting line VL.

4 shows a possible embodiment of the present invention, wherein the reactance elements of the base circuit elements are designed as inductors and wherein the signal path between the two base circuit elements connected has a series resonator SR3.

5 shows an advantageous embodiment of the present invention, wherein compared to embodiment according to 4 two more series resonators SR4 and SR5 are connected in the signal path, and wherein a further inductance IN is electrically connected to the signal path output. Between the further inductance IN and the series resonator SR5, a further parallel resonator PR5 is electrically conductively connected in a further parallel path with the signal path and with ground.

The 6a and 6b show four curves of the insertion loss of a duplexer, of which at least one filter comprises the filter circuit according to the invention. 6a shows the insertion loss (in dB) versus frequency in the range of 1800 to 2300 MHz. The unilaterally open rectangles specify the specifications of the respective mobile radio standard to be complied with. The two curves DTxa and DRxa show the insertion loss of a transmission path or of a reception path of a filter circuit contained in the duplexer, wherein the reactance elements have vanishingly small reactance values. This case thus corresponds to a conventional ladder type structure.

The Two curves DTxb and DRxb show the insertion loss a send path or a receive path of a duplexer Filter circuit, wherein the reactance elements finally large Reactance values (0.5-2 nH) have. In the curve DRxb are three local minima at 2010 MHz, at 2030 MHz and at 2080 MHz too detect. These are the three poles mentioned in the description, one of which is able to shift by varying the reactance without degrading the remaining filter characteristics.

In contrast, the shows 6b the isolation between rule transmission path and receive path of a duplexer, which uses a filter circuit according to the invention. The curves Ia respectively. ib again differ in the inductance of the interconnected reactance elements: the curve ib shows the insulation with vanishingly low inductance, while the other curve Ia shows the insulation at finite inductance of the reactance elements. Especially in the transmission band, the isolation is improved by about 2-3 dB.

A Filter circuit is not limited to one of the described embodiments limited. Variations, which z. B. even more resonators, Reactance elements or any combinations thereof in the signal path or in described or additional parallel paths include, likewise embodiments of the invention represents.

BSE, BSE1, BSE2

Schasisschaltungselement

DRxa

attenuation curve of the reception path without reactance element

DRxb

attenuation curve of the reception path with reactance element

DTxa

attenuation curve of the transmission path without reactance element

DTxb

attenuation curve the transmission path with reactance element

fap

Antiresonance frequency of a parallel resonator

fas

Antiresonance frequency of a series resonator

frp

resonant frequency a parallel resonator

frs

resonant frequency a series resonator

Ia

isolation curve without reactance element

ib

isolation curve with reactance element

IN

inductance

MA

Dimensions

PP, PP11, PP12, PP21, PP22

parallel path

PR, PR11, PR12, PR21, PR22, PR5

parallel resonator

RE

reactance

SA

signal output

SE

signal input

SP

signal path

SPA

Signal path output

SPE

Signal path input

SR, SR1, SR2, SR3, SR4, SR5

series resonator

VA

connection port

VL

connecting line

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• DE 102006005298 A1 [0002]
• EP 0995265 B1 [0003]
• - EP 1196991 B1 [0004]
• - DE 19932649 A1 [0005]

Claims (26)

Filter circuit with ladder-type-like Structure formed on a chip comprising - one Signal path (SP), which is a signal path input (SPE) with a signal path output (SPA) connects, A ground connection (MA), - one first and second base circuit elements (BSE1, BSE2) ever A signal input (SE1, SE2), - one Signal output (SA1, SA2), - a connection connection (VA1, VA2), - A series resonator (SR1, SR2), electric interconnected between signal input (SE1, SE2) and signal output (SA1, SA2), - one Resonator (PR11, PR12), electrically between signal input (SE1, SE2) and connection connection (VA1, VA2) interconnected, - one second resonator (PR21, PR22), electrically between connection terminal (VA1, VA2) and signal output (SA1, SA2) interconnected, - one Reactance element (RE1, RE2), electrically between connection terminal (VA1, VA2) and ground (MA) connected, the first and the second base circuit element each via their Signal inputs and signal outputs electrically serial are interconnected in the signal path. Filtering circuit according to claim 1, wherein the signal path (SP) comprises a third series resonator (SR3), the third one Series resonator SR3 between signal output (SA1) of the first base circuit element and the signal input (SE2) of the second base circuit element is interconnected. Filtering circuit according to claim 2, wherein the signal path (SP) a fourth and a fifth series resonator (SR4, SR5), wherein the fourth series resonator SR4 is between signal path input (SPE) and the signal input (SE1) of the first base circuit element is interconnected, and the fifth series resonator (SR5) between the signal output (SA2) of the second base circuit element (BSE2) and is interconnected to the signal path output (SPA). Filter circuit according to claim 1 or 2, comprising a fifth parallel resonator (PR5) electrically connected between Signal path output (SPA) and ground (MA) is interconnected. Filter circuit according to one of claims 1-3, comprising an inductance IN electrically connected to the Signal path output (SPA) is connected. Filter circuit according to one of claims 1-4, wherein the reactance elements (RE1, RE2) in the different base circuit elements (BSE1, BSE2) have different impedances. Filter circuit according to one of claims 1-5, wherein the reactance elements (RE1, RE2) in the base circuit elements (BSE1, BSE2) are inductors. Filter circuit according to one of claims 1-6, wherein the resonators are realized as SAW resonators. A filter circuit according to claim 8, wherein the SAW resonators built on a chip of lithium tantalate or lithium niobate are. Filter circuit according to one of claims 1-7, wherein the resonators are realized as BAW resonators. The filter circuit of claim 10, wherein the BAW Resonators are arranged on a silicon chip. Filter circuit according to one of claims 1-11, wherein the electrical connection lines (VL1, VL2) as conductor tracks are arranged on the chip. Filter circuit according to one of claims 1-12, in which the chip is on a multilayer carrier substrate is arranged with integrated wiring. Filtering circuit according to claim 13, wherein the reactance elements (RE1, RE2) as structured metallizations in the carrier substrate are formed, wherein the carrier substrate is an LTCC substrate includes. Filter circuit according to one of claims 1-14, comprising a strain gauge filter electrically connected to the signal path input (SPE) or the signal path output (SPA). Filter circuit according to one of claims 1-15, wherein the signal path (SP) is part of a bandpass filter. The filter circuit of claim 16, wherein the bandpass filter Is part of a receive filter. The filter circuit of claim 17, wherein the receive filter Part of a duplexer is. Filter circuit according to claim 18, wherein the duplexer with substantially unchanged insertion loss of the receive filter (DRxb) improved isolation in the frequency range of the transmit filter ( ib ) having. Filtering circuit according to claim 18, wherein the duplexer with substantially unchanged Isolati on in the frequency range of the transmission filter ( ib ) has an improved insertion loss of the receive filter (DRxb). Method for optimizing insertion loss filter circuits of ladder-type like structure, comprising the following steps: a) providing a circuit with ladder-type structure, which is formed on a chip and a signal path (SP) and four parallel paths (PP11, PP21, PP12, PP22), where the parallel paths connect the signal path to ground connect, and wherein in the signal path (SP) two series resonators (SR1, SR2) each between the branch points of the first and second and the third and fourth parallel paths are interconnected, and in each of the parallel paths, a parallel resonator (PR11, PR21, PR12, PR22) is interconnected, b) Optimizing the bandpass filter characteristic by adjusting the characteristics of the series and parallel resonators (SR1, SR2, PR11, PR21, PR12, PR22), c) Electrical interconnection the ground-side ends of the first and second parallel paths PP11 and PP21 through a first electrical connection line (VL1) and the ground-side ends of the third and fourth parallel paths PP12 and PP22 through a second electrical connection line (VL2), d) Create one additional pole (PS1, PS2) per electrical connection line (VL1, VL2) by electrical interconnection each of a reactance element (RE1, RE2) between each electrical Connecting line (VL1, VL2) and ground (MA), e) adjusting the Impedances of the reactance elements (RE1, RE2), with the additional Pole positions (PS1, PS2) positioned in or near the desired stopband become. The method of claim 21, wherein the additional Pole positions (PS1, PS2) positioned at different frequencies become. A method according to any one of claims 21-22, wherein the impedance of the reactance elements (RE1, RE2) is increased, around the frequency of the additional poles (PS1, PS2) to humiliate. A method according to any one of claims 21-23, wherein used as reactance elements (RE1, RE2) inductors whose adaptation is made in the range of 0.5 nH to 2 nH becomes. A method according to any of claims 21-24, wherein the electrical connection lines (VL1, VL2) formed on the chip become. A method according to any of claims 21-25, wherein as reactance elements (RE1, RE2) discrete components are used, which is mounted together with the chip on a carrier substrate become.