WO1999010761A2 - Quasi rectangular wave filter - Google Patents

Abstract

The invention relates to a quasi rectangular wave filter for electromagnetic waves. One such quasi rectangular wave filter should have a flat amplitude characteristic, steep flanking filters and good signal suppression in the adjacent channel. According to the invention, the quasi rectangular wave filter is comprised of a coupling element with a coupling factor power output of kV1,2=(1/2)(1±1/∑2) or from kV = 0,5, said element being coupled to a resonance element via two lines which are equal in length.

Description

description

Quasi-rectangular filter

description

The invention relates to a quasi-rectangular filter for electromagnetic waves. Such filters can be designed both as optical and as electrical filters.

With optical filters, the intensity (neutral filter such as gray filter, gray wedges), the spectral composition (absorption filter, interference filter such as line filter, edge filter, waveguide filter with reflective fiber grating, AWG - arrayed waveguide grating) or the polarization state (polarization filter) of the light can be changed. These filters are key components in optical transmission systems that use the WDM (wavelength division multiplexing) or OFDM (optical frequency division multiplexing) technology. In optical networks e.g. WDM filters based on fuse couplers for low-loss separation or merging of WDM signals and in optical direct receivers are tunable filters, such as Fabry-Perot filters, for frequency selection of OFDM signals and for suppression of ASE (amplified spontaneous emission - Light noise) from optical fiber amplifiers.

The filters currently available are limited in their selection effect and their filter properties are largely determined by the design principle used.

In "NTZ - Nachrichten Technische Zeitschrift" 47 (1994) June, No. 6, pp. 418-422, Fabry-Perot filters are reported as tunable optical filters for direct receivers. In "Optical Fiber Communications Systems", Leonid Kazovsky , Sergio Benedetto, Alan Willner, 1996 ARTECH HOUSE, ISBN 0- 89006-765-2, pp. 646-648 describes the functioning of such a Fabry-Perot filter.

To ensure highly selective filtering, the mirror / resonator surfaces of such filters must be of very good quality, i.e. the power reflection factor must be> 0.95. However, the implementation of such a power reflection factor and the mechanical structure are associated with high costs.

It is an object of the invention to provide a quasi-rectangular filter for electromagnetic waves, which is both inexpensive to manufacture and guarantees the properties desired for a periodic bandpass filter, such as flat pass characteristics, steep filter edges and good signal suppression in the adjacent channel.

The object is achieved in that a coupling element with

a power coupling factor of kV _{1 2} = - ⁽ l ± -τ P = or of kV = 0.5 above

2 i. two conductors of the same length is connected to a resonance element.

The optical quasi-rectangular filters according to the invention consist of a

<1 ^Λ optical 2x2 coupler with a power coupling factor of kVι, ₂ = - 1 +

S or kV = 0.5, which is connected to an optical resonator that has a Fabry-Perot power transfer function via two optical fibers of equal length.

By connecting an optical coupler, which is hereinafter referred to as a pre-coupler, in front of the above-mentioned optical resonator, the transmission properties of the optical resonator are surprisingly influenced to such an extent that a changed, novel transmission behavior results. The function of the optical quasi-rectangular filter according to the invention is a periodic quasi-rectangular filter with a lower equidistant with respect to the optical frequency Pass-through and high blocking attenuation in the adjacent channel with a very flat course of the attenuation in the transmission and reflection range and with a broad quasi-linearly increasing or decreasing attenuation in the frequency range between the extreme values.

At the upper or lower input of the quasi-rectangular filter according to the invention, an optical input signal (complex field size) is fed in, which is divided into two parts that are phase-shifted by 90 degrees and differently damped. These signals pass through the two waveguides of equal length to an optical resonator, which is characterized by the Fabry-Perot transfer function. Each of the two signals leads to a wave reflected by the resonator and transmitted through the resonator. These four waves then run back in pairs over the two waveguides of the same length to the pre-coupler, where they overlap constructively and in phase with the same polarization state, so that complementary power transfer functions with quasi-rectangular characteristics result at the lower and at the upper output.

The optical power amplitudes of the quasi-rectangular optical filter depend on the polarization state of the light, on the power losses and the reflectivity of the mirror interfaces, the power losses in the optical resonator and in the pre-coupler and also on the attenuation of the optical fibers and the optical input connectors. The frequency dependence of the power transfer function is determined by the lengths and the refractive index of the optical fibers in the resonance path of the optical resonator.

In embodiments of the invention with their own worthy of protection, the optical resonator is a Fabry-Perot filter with a power reflection factor of r = 3 - V8 ≡ 0.172 or an optical 2x2 coupler, hereinafter referred to as Fabry-Perot coupler two ideal mirrors arranged at the ends of the longitudinal or cross path. If the two mirrors are arranged at the ends of the longitudinal path of the Fabry-Perot coupler, this has a power coupling factor of k = 0.828, if the two mirrors are arranged at the ends of the cross path of the Fabry-Perot coupler, the power coupling factor is k = 0.172. If a minimum blocking attenuation in the adjacent channel of -20 dB is specified, the following tolerance-related power coupling factors result: k = 0.828 ± 0.045 and kV = 0.854 ± 0.035. The mirrors are either formed from dielectric layers on the end faces of the substrate (for example by vapor deposition of the end faces of the wafer) or metal mirrors, which are arranged in pre-etched slots at the ends of the resonance path, or are Bragg gratings, which are used for example in the construction of integrated technology into the waveguide.

Instead of the two mirrors, a 3dB coupler with an optical fiber bridge on the output side, a mirror coupler, can also be used. This has two reflective inputs that can be connected either at the ends of the longitudinal or the cross path.

In a further embodiment of the invention, the optical resonator with the desired Fabry-Perot transfer function can also be constructed from two 2x2 couplers bridged on the output side, which are connected in series via a bridge on the input side. The possible power coupling factors k _1/2 = 0.045 or 0.955 can be assigned to the couplers in any combination.

The last variant for a Fabry-Perot resonator consists of two 2x2 couplers connected in a Mach-Zehnder arrangement with four mirrors on conductors of the same length and a detour line between the two couplers.

According to the principle according to the invention of suitably transforming the back and forth electromagnetic waves by means of an upstream coupling element, each of the above-mentioned resonators is preceded by a 2x2 coupler with fixed power coupling factors. These arrangements then form the different embodiments of the quasi-rectangular filter. Two further functions can be implemented by changing the temperature and the associated change in refractive index in the optical waveguide sections: The tuning of the power spectral function as a function of the frequency with constant power amplitudes can be achieved by locally influencing the temperature of the waveguide in the resonance path. In the case of filters with a pre-coupler, the switch from reflection to transmission mode, based on a specific input and a specific frequency, can be achieved by a temperature gradient between the two waveguides between the pre-coupler and the optical resonator with Fabry-Perot transfer function. The filters according to the invention can thus also be used as an active component - and thus even more flexibly.

In its various embodiments of the invention, the optical filter according to the invention can be constructed from discrete optical components with extremely short optical fibers and in a compact, encapsulated construction or in an integrated optical construction. A particular advantage of the integrated structure is that the optical waveguide is voltage-free

Structure and small dimensions are polarization-maintaining, so that the invariability of the polarization state is guaranteed within the filter. In addition, the lengths of the optical fibers can be determined with sufficient accuracy (<λ / 2), so that the conditions of identical lengths of the optical fibers in pairs both between the pre-coupler and the Fabry-Perot coupler and in the resonance path between the Fabry-Perot coupler and the Mirroring or between the Fabry-Perot coupler and the 3dB coupler with optical fiber bridge (mirror coupler) can be fulfilled.

Basically, electrical components of the same type can be used instead of the optical ones. The optical couplers are replaced by electrical 3 dB or directional couplers. The mirrors are replaced by either short-circuit caps ("Short" with a voltage reflection factor r = -1) or open outputs ("open" with r = +1). The main difference to the optical field of application is that the transmission properties of the filter due to the complex voltage Transfer function (amount, phase, group term) is given. In contrast, the optical field size E behind the optical filter (through the photodiode) is converted into an optical power (P _opt . = E x E conjugate complex). This means that the transmission properties of the filter have to be described here by the optical power transmission function. In addition, the problem of maintaining the polarization state of the wave is eliminated in the electrical field. In the optical range, the full functionality of the optical filter is only guaranteed if the interferometric superimposition of the partial waves is not disturbed by polarization fluctuations.

Further advantageous embodiments of the invention are specified in the subclaims or are explained in more detail below together with the description of preferred embodiments of the invention with reference to the drawings.

Show:

Figure 1 shows a first basic embodiment of the quasi-rectangular filter (QRF) according to the invention as an optical filter. FIG. 2 shows the dependency of the power transmission factor on the optical frequency for a known Fabry-Perot filter and the power transfer functions (LÜF) for the quasi-rectangular filter according to the invention obtained therefrom according to FIG. 1 in comparison;

Fig. 3 amount and group delay (dashed) for the field size E at the output of the quasi-rectangular filter over the optical frequency;

4 shows a second exemplary embodiment of the quasi-rectangular filter according to the invention with a Fabry-Perot coupler;

5 shows a third exemplary embodiment of the quasi-rectangular filter according to the invention with Fabry-Perot coupler and mirror coupler; 6 shows a fourth exemplary embodiment of the quasi-rectangular filter according to the invention with two optical couplers connected in series on the input side and bridged on the output side;

Fig. 7 shows a fifth embodiment of a steep quasi-rectangular filter consisting of a pre-coupler and two Mach-Zehnder couplers two mirrors each, over pairs of different lengths

Optical fibers are connected to the couplers; Fig. 8 power transmission functions (transmission dashed) in

Dependence on the optical frequency for the quasi-rectangular filter according to FIG. 7;

Fig. 9 Amount and group term (dashed) for the field size E am

Output of the quasi-rectangular filter according to Figure 7 on the optical

Frequency; 10 shows a sixth exemplary embodiment of a quasi-rectangular filter consisting of a pre-coupler and two Mach-Zehnder couplers with a total of four mirrors, which are connected to the two couplers via optical fibers of the same length; Figure 1 1 an optical muxer / demuxer using two quasi-rectangular filters according to the invention. Fig. 12 is an optical circuit with two over an optical fiber bridge in

Series connected quasi-rectangular filters according to the invention; Fig. 13 shows the curve of the power transmission factor of the optical

12 as a function of the light wavelength; 14 shows an optical circuit with two quasi-rectangular filters according to the invention connected in series via an optical isolator;

Fig. 15 shows the curve of the power transmission factor of the optical

14 as a function of the light wavelength; 16 shows an exemplary embodiment of an electrical quasi-rectangular filter analogous to the optical quasi-rectangular filter according to FIG. 4 using microstrip technology;

17 shows an exemplary embodiment of an electrical quasi-rectangular filter analogous to the optical quasi-rectangular filter according to FIG. 7 in microstrip

Technology; 18 Amount of the electrical voltage transfer function and group delay for the quasi-rectangular filter analogous to FIG. 7 over the electrical frequency. In Fig. 1, an optical quasi-rectangular filter is shown, which according to the invention from a 2x2 coupler VK with power coupling factors of 1 ^f 1 kVι, ₂ = - l ± - _/ = and a Fabry- downstream of the 2x2 coupler VK

2 ϊ.

Perot filter FPF exists. The Fabry-Perot filter FPF has a qualitative Fabry-Perot transfer function and a technically unusual power reflection factor of r = 3 - δ.

2 shows a comparison of the power transmission factors of a known Fabry-Perot filter (dashed line below) and the optical filter according to the invention derived therefrom (solid line for transmission, dashed line above for reflection) as a function of the optical frequency. The characteristics of the filter according to the invention can be clearly seen, which are changed by influencing the unusual transmission properties of the optical resonator by connecting a 2x2 coupler with a likewise unusual power coupling factor. The filter according to the invention is a periodic quasi-rectangular filter which is equidistant with respect to the optical frequency. The relatively large linear turning point range allows low-distortion FM-AM conversion (frequency modulation, amplitude modulation) of modulated signals. In addition, the optical filter according to the invention can be used for the periodic suppression of light noise.

3 shows the magnitude of the optical field size E and the group delay before the power is formed by a photodiode. The edges of the amount of the field size E do not run as steeply over the optical frequency as those of the optical power. The steeper edges of the power transfer function from FIG. 2 are based on the field size being squared by the photodiode (P _opt = E x E conjugate complex). The distortion of the phase curve over the optical frequency leads to distortion of the mean group delay (GLZ), which is decisive for the distortion-free transmission of narrow frequency groups. The mean group delay is determined by the wave velocity in the waveguides and their total length. 4 shows a further embodiment of the optical filter according to the invention. The pre-coupler VK mentioned here is via two optical fibers LWLι, _{2 of the} same length with the Fabry-Perot coupler FPK connected, which consists of an optical 2x2 coupler with a power coupling factor of k = 1 - (3 - Vδ) and two mirrors Si and S ₂ at the ends of the longitudinal path. It is also possible to arrange the mirrors at the ends of the cross path of the Fabry-Perot coupler FPK, which in this case has a power coupling factor of 3 - δ. The upstream 2x2 coupler VK responsible for the transformation of the field size transfer functions of the Fabry-Perot coupler FPK must already have the above

have mentioned values for the power coupling factor kVι, ₂ = - 1 ± -.

A filter designed in this way is suitable for a “free spectral range” (fsr) up to 200 GHz if, for example, the coupler zone of the integrated coupler is minimal Ik = 0.5 mm and the total length of the waveguides to the mirrors is I = 0.5 mm The "free spectral range" is calculated according to: fsr = Co / n (lk + I), where co is the speed of light and n is the refractive index of the optical waveguide (for SiO ₂ , for example, n = 1, 5).

The refractive index and the length of the waveguides can be influenced by locally heating the waveguides in the resonance path. This allows the power spectral function to be tuned slightly over the wavelength.

FIG. 5 shows a variant of the optical filter according to the invention, in which a mirror coupler SK with a right-hand optical fiber bridge B _{r is} arranged instead of the technically complex mirror. The two left inputs of the mirror coupler SK act like two mirrors at k = 0.5. However, the “free spectral range” is reduced by increasing the effective resonator length; this filter is suitable for a “free spectral range” <50 GHz. The optical fiber bridge B _r can be used to control the "free spectral range" by changing the temperature (changing the optically effective length of the resonance path). Fig. 6 shows an embodiment of the invention, in which the Fabry-Perot filter is replaced by two optical 2x2 couplers Ki and K ₂ , the input side with an optical fiber bridge Bι (length b) connected in series and the output side with one Optical fibers are bridged. This arrangement acts like a Fabry-Perot filter if the couplers have different or the same power coupling factors of k ₂ = 0.045 or 0.955. The upstream 2x2 coupler VK also brings about the transformation of the field sizes and thus the generation of the power spectral function of the quasi-rectangular filter according to the invention. This pre-coupler VK has a power coupling factor of kι, ₂ V =

The "free spectral range" of this embodiment of the invention

is calculated with a length Ik of the coupler zone from fsr = Co / n (l + b + 2-lk) and reaches values of <50 GHz. In this embodiment too, the temperature of the bridges B _r and B can be changed, as a result of which the power spectral function can be tuned slightly over the wavelength.

A further embodiment for a quasi-rectangular filter with even steeper flanks than that shown in FIG. 4 consists of two 2x2 couplers K (k = 0.25 / 0.75) connected in a Mach-Zehnder arrangement with four mirrors, a detour line LU between the couplers K and a pre-coupler VK (kV = 0.5) according to FIG. 7. The filter consists of four coupled resonators, three of which differ from one another in pairs (pair LA, pair LB) of mirror lines of equal length. The "free spectral range" results from the lengths in the shortest resonance path. The lengths of the mirror feed lines on each coupler side at k = 0.25 must meet the following condition: LB / LA = 3 + LU / LA. In this case, the "Free spectral range" of the shortest resonance path to that of the longest as 3: 1 and to that of the middle resonance path as 2: 1. For k = 0.75, LA has to be exchanged for LB, ie the longer ones take the place of the shorter mirror leads and vice versa. II

This filter is somewhat asymmetrical with regard to the transmission and reflection range (Fig. 8, dashed line transmission), but allows a relatively large coupling factor tolerance of, for example, k = 0.25 ± 0.06 if one is just about tolerable reflection attenuation assumes a transmission range of -20 dB. This property is important in the case when the power coupling factors of the optical couplers should have a frequency dependency. If the pre-coupler is omitted, the wider transmission transfer function (FIG. 8) becomes the complementary, equally wide reflection transfer function (solid line).

FIG. 9 shows the amount and the group delay for the field size E of the quasi-rectangular filter according to FIG. 7 over the optical frequency. The group delay shows distortions that are symmetrical to the center of the transmission range.

The filter according to FIG. 10 has the same structure as the filter according to FIG. 7. The first filter differs from the last one in three points: the power coupling factor of the pre-coupler VK is kV = 0.146 or 0.854; the Mach-Zehnder couplers both have either k = 0.293 or k = 0.707 (provides the complementary power transfer function) and the mirror leads are of equal length. The power transfer function is identical to that of the filter according to FIG. 4. The "free spectral range" is determined by the identical lengths of the four coupled resonators. Since the four mirror feed lines are of the same length, they can be guided to one side of the waveguide by means of suitable alignment of the two couplers without curvatures of the conductors, and there at one interface at one interface In addition, the “free spectral range” can be determined by selecting the detour line length LU and, if necessary, fine-tuned by influencing the temperature without affecting the symmetry of the resonators. A disadvantage is the higher effort compared to the structure according to FIG. 4 (one coupler, two mirrors).

Two identical quasi-rectangular filters QRF according to the invention according to FIG. 1 are shown in FIG. 11 as part of a Muxer / Demuxer arrangement. An optical filter QRF is arranged in each case in a connection path between two 3dB couplers K _3d B. If, for example, a wave in the transmission range of the power spectral function T and a wave in the reflection range R are now applied to the upper input shown, the T signal and the R signal appear lossless at separate outputs (demuxers). The Muxer function is implemented by swapping inputs and outputs. The spectral functions for transmission and reflection are identical to those of the quasi-rectangular filter QRF according to the invention. In comparison, with a single quasi-rectangular filter QRF, the R component is reflected at the input, the T component reaches the lower output. The described arrangement of two optical filters according to the invention has the property of an optical attenuator when a temperature gradient is generated between the upper and lower connection path and the associated change in refractive index, the T-wave due to the optical path length difference between the upper and lower optical waveguide from the lower transmission output T 1 can be continuously faded to the upper transmission output T 2. The same applies to the R wave. In the event of a corresponding temperature change, this is faded from the lower left output R to input E (mirror function).

FIG. 12 shows two identical quasi-rectangular filters QRF according to FIG. 1, which are connected in series on the input side via an optical waveguide bridge Br of length Ib. This bridge Br forms a new resonance circuit via both quasi-rectangular filters QRF, which distorts the QRF power transfer function, in particular on the flanks, so that steeper flanks are created.

The curve of the power transmission factor of the optical circuit described as a function of the optical wavelength is shown in FIG. 13 in comparison to that of an individual filter. There are two types of steep wall filters if the condition lb = m λ / 4 (m even or odd) is met. This condition can be realized by influencing the temperature of the bridge Br. 14 shows an optical circuit with two quasi-rectangular filters QRF according to the invention connected in series via an optical isolator Iso. This optical isolator Iso, which has increased attenuation, decouples both filters QRF from one another, so that stable filter shapes are formed regardless of the length of the optical waveguide. If one selects the "free spectral ranges" of the two sub-filters in a ratio of, for example, 11: 1, then a comb filter is obtained even if different coupling factors are selected for the pre-couplers (kVi = 0.146 for coupler 1 and kV ₂ = 0.854 for coupler 2) about four filter curves with maximum transmission can be used, which can be clearly seen in the curve of the power transmission factor of the optical circuit shown in Fig. 14 as a function of the optical light wavelength compared to the curve of an individual filter shown in Fig. 12. The curve shown in Fig. 12 optical circuitry also allows the creation of comb filters, but the filter curves on the flanks are distorted.

The exemplary embodiments for electrical quasi-rectangular filters described below each have a structure analogous to corresponding optical filters.

For the electrical quasi-rectangular filter shown in FIG. 16 with a construction analogous to the optical filter according to FIG. 4, a construction proposal in microstrip technology is shown. In order to achieve a compact design, the two directional couplers are arranged orthogonally in two layers with a “ground plane” in between. The two electrical leads of exactly the same length L from the first directional coupler used as a pre-coupler (kV = 0.854 or 0.146) pass through two penetration points D. to the second directional coupler acting as a resonator (k = 0.828), which can be terminated with either two "shorts" or two "opens". Depending on the type of termination, complementary quasi-rectangular filter filters result.

Transfer functions. The design proposal for the electrical quasi-rectangular filter shown in FIG. 17 with a structure analogous to the optical filter according to FIG. 7 shows a possible structure in microstrip technology with a possibility of adjustment for the “free spectral range” with the aid of the detour length 17 has a pre-coupler VK with a power coupling factor kV = 0.5 and two directional couplers (resonators) connected in a Mach-Zehnder arrangement with a power coupling factor k = 0.25 or 0.75 for both directional couplers, the terminating leads for each directional coupler being of different lengths.

Another embodiment (not shown) of an electrical quasi-rectangular filter has a structure analogous to the structure of the optical filter according to FIG. 10. The directional coupler used as a pre-coupler has a power coupling factor kV = 0.146 or 0.854. The power coupling factor of the directional coupler acting as a resonator in a Mach-Zehnder arrangement is k = 0.293 or 0.707. The termination leads of the resonator are of the same length.

The voltage transmission properties of the quasi-rectangular filter shown in FIG. 17 are characterized by the amount of the voltage transmission and the group delay over the electrical frequency. The group delay distortions run symmetrically to the center of the transmission area (see Fig. 18).

The functionality of the individual embodiments of the electrical filters could be demonstrated by experiments with commercial directional couplers.

Claims

claims

1. Quasi-rectangular filter for electromagnetic waves, characterized in that

1 a coupling element with a power coupling _factor of kVι _ι2 = - 1 + or

of kV = 0.5 is connected to a resonance element via two lines of equal length.

2. Filter according to claim 1, characterized in that it is designed as an optical filter, having an optical 2 x 2-

Coupler with a power _{coupling factor} of kV _1ι2 = - or of

kV = 0.5 (pre-coupler), which is connected to an optical resonator having a Fabry-Perot power transfer function via two optical fibers of equal length.

3. Filter according to claim 2, characterized in that the optical resonator with Fabry-Perot transfer function is a Fabry-Perot filter (FPF) with a power reflection factor of r = 3 - δ.

4. Filter according to claim 2, characterized in that the optical resonator with Fabry-Perot transfer function from an optical 2x2 coupler and two ideal mirrors (Si, S ₂ ) which are arranged at the ends of the longitudinal or cross path , is formed.

5. Filter according to claim 4, characterized in that the two mirrors (Si, S ₂ ) are arranged at the ends of the longitudinal path of the optical 2x2 coupler, the power coupling factor k = 1 - (3 - 8) = 0.828.

6. Filter according to claim 4, characterized in that the two mirrors (S ^, S ₂ ), at the ends of the cross path of the optical

2x2 couplers are arranged, the power coupling factor being k = 3 - δ = 0.172.

7. Filter according to claim 4, characterized in that the mirrors are formed from dielectric layers on the end faces of the substrate on which the components are arranged.

8. Filter according to claim 4, characterized in that the mirror is designed as a metal mirror and are arranged in pre-etched slots at the ends of the resonance path.

9. Filter according to claim 4, characterized in that instead of the ideal mirror (Si, S ₂ ) Bragg grating are provided.

10. Filter according to claim 4 and 5 or 6, characterized in that the optical resonator with Fabry-Perot transfer function is an optical

2x2 coupler (FPK) with a power coupling factor of ki = 1 - (3 - 8) (longitudinal path) or k ₂ = 3 - Vδ (cross path), which is connected to a 3dB coupler with a right-sided optical fiber bridge (B _r ), a mirror coupler (SK), is connected.

11. Filter according to claim 2, characterized in that the optical resonator with Fabry-Perot transfer function is formed from two 2x2 couplers (K _1t K ₂ ) bridged on the right-hand side, which are connected to one another via a left-hand optical fiber bridge (Bι), being the

Power coupling factors of both couplers (Ki, K ₂ ) kι / ₂ = 0.045 or kι ₂ = (1 -

0.045), where kι _{/ 2 are the} same size or different sizes.

12. Filter according to claim 1, characterized in that the downstream having a power coupling factor of kV = 0.5 pre-coupler resonator made of two Mach-Zehnder arrangement connected 2x2 couplers with a power coupling factor of k = 0.25 or k = 0.75 with four mirrors with pairs of different lengths of supply lines, which have a detour line (LU) between their upper connections.

13. A filter according to claim 2, characterized in that the pre-coupler having a power coupling factor of kV = 0.146 or kV = 0.854 has a downstream resonator made of two 2x2 couplers connected in a Mach-Zehnder arrangement with a power coupling factor of k = 0.293 or k = 0, 707 with four mirrors with leads of equal length.

14. Filter according to claim 12, characterized in that the ratio of the lengths of the mirror leads of the condition

LB / LA = 3 + LU / LA is sufficient.

15. Filter according to at least one of claims 2 to 14, characterized in that each has an optical filter with quasi-rectangular characteristics (QRF) in a connection path between two 3 dB couplers (K ^ _B ) with a mux / demux function is arranged.

16. Filter according to at least one of claims 2 to 15, characterized in that

Means for setting a temperature change on the optical waveguide sections to influence the refractive index and the conductor length in the resonance path and / or means for generating a temperature gradient between the feed lines between the pre-coupler and the optical resonator are provided.

17. Filter according to claim 2, characterized in that two optical filters (QRF) are connected in series via an optical fiber bridge (Br) on the input side.

18. Filter according to claim 2, characterized in that two optical filters (QRF) via an optical isolator (Iso) on the input side

Series are connected.

19. Filter according to at least one of claims 2 to 18, characterized in that the filter is constructed from discrete optical components in a compact design with short, equally long optical fibers.

20. Filter according to at least one of claims 2 to 16, characterized in that the filter is constructed in an integrated optical design.

21. Filter according to claim 1, characterized in that it is designed as an electrical filter in which a directional coupler is arranged as a pre-coupler and one or two directional couplers are arranged as a resonance element, the outputs of which, apart from the signal output, with "shorts" or "Opens" are completed.

22. Filter according to claim 21, characterized in that the power coupling factor of the directional coupler arranged as a pre-coupler is kV = 0.146 or kV = 0.854 and a directional coupler with k = 0.828 or k = 0.172 as a Fabry-Perot resonator coupler with two terminations is arranged on the longitudinal or cross path of the resonator.

23. Filter according to claim 21, characterized in that the pre-coupler has a power coupling factor of kV = 0.5, the terminating leads are of unequal length and the power coupling factor of the two Mach-Zehnder couplers forming the resonator k = 0.25 and k = Is 0.75.

24. Filter according to claim 21, characterized in that the pre-coupler has a power coupling factor of kV = 0.146 or kV = 0.854, the power coupling factor of the two Mach-Zehnder couplers forming the resonator is k = 0.293 or k = 0.707 and the terminating lines of the resonator are of equal length.