SE518713C2 - Method and apparatus for signal filtration consisting of a passive filter with complex impedance - Google Patents

Abstract

The present invention relates to a filter (45) for filtering signals in a telecommunications system, a method of designing said filter, and a corresponding splitter filter. The inventive filter (45) is characterised in that it is passive and has a complex impedance which gives good impedance matching to the complex impedance of a transmission line. Because the filter is passive, it does not need to be powered and can thus be placed in locations that lack a power supply. The filter will also function in the event of a power failure. Because the filter has an impedance which can be well matched to the complex impedance of a transmission line, problems relating to echo and side tones can be minimised. The design of the inventive filter has been made possible by utilising that a certain determined level of losses can often be accepted in respect of the filter. The impedance of the filter can be made similar to the impedance of a transmission line, by intentionally introducing into the filter losses (15, 17) which assist in making the impedance of the filter more complex. This can be achieved without the use of active elements.

Description

o n '10 15 20 25 30. 35 2 To obtain echo, it is desirable that the nominal optimal transmission characteristics and impedance of the splitter filter be similar to the impedance of the transmission line or the impedance that results from a combination of the transmission line impedance and a terminating impedance in the transmission line remote end. The impedance of a transmission line is complex while the terminating impedance can be either complex or resistive. The term 'transmission line impedance' in the following includes both the case when the transmission line impedance is meant and the case when the combination of the transmission line impedance and the terminating impedance is meant.

It is particularly important to avoid echo in the speech band and it is important that satisfactorily the impedance of the low-pass filter in particular is matched on that of the transmission line. Since the impedance of the transmission line is complex, it is desirable that the impedance of the low-pass filter is also complex. It is also desirable that the filter be passive to avoid power supply problems and to ensure that the filter continues to operate in the event of a power failure. However, it has not heretofore been known how to provide passive low-pass filters with an impedance that is complex in such a way that it can satisfactorily match the complex impedance of a transmission line.

One solution has been to embed a passive low-pass filter with resistive impedance between General Impedance Converters (GIC). The GICs transform the resistive impedance of the filter so that the arrangement of GICs and filters, seen from the transmission line, has complex impedance. The GICs used in this context contain transformers and amplifiers and are thus active. Thus, as a whole, the entire filter arrangement with and GICs becomes active and the desired power supply still becomes an inevitable low-pass filter with this method.

The technique of embedding a filter between two GICs to obtain a resistive impedance with resistive impedance is known from, for example, U.S. Patent No. 5,623,543 and the article "ADSL and VADSL Splitter Design and Telephony Performance" by John Cook and Phil Sheppard, IEEE selected Vol. 13, no.9 December 1995. the patent and the said article also discuss the importance of published in the Journal on areas in Communications, In the said impedance matching.

Passive filters for systen1 where different types of information are sent over one and the same transmission line in different frequency bands are described in the U.S. patents US-5,848, 150 and US-4,764,922. However, none of these documents addresses the problem of impedance matching to the complex impedance of an end transmission line.

INFORMATION OF THE INVENTION In a system where different types of telecommunication traffic are transmitted over a common transmission line in different frequency bands, splitter filters, comprising a high-pass filter and a low-pass filter, are used to separate the different types of traffic. In such a system, the telecommunication traffic passing through the low-pass filter is often voice traffic associated with telephone calls.

Echo and side tones are very disturbing during a phone call and therefore you want as much as possible. to avoid the occurrence of these phenomena. As mentioned above, good impedance matching between the low-pass filter and the transmission line means that the transmission properties are good and that the problems near echo and sidetone become small.

A problem with the above-mentioned active filters is that they have to be powered. This can often be problematic, especially when it is desirable to place the filter in a place where power supply does not otherwise exist. Another problem with active filters is that they do not work in the event of a power failure.

Thus, passive filters are preferred.

The present invention addresses the problem of how a filter can be provided which provides both good impedance matching to a transmission line, or to a similarly complex impedance, and which is simultaneously passive. The object of the invention is thus to provide a passive filter with complex impedance and a method for constructing such a filter. To solve the above-mentioned problems, the impedance of the filter must be complex in such a way that good impedance matching against an impedance similar to the complex impedance of a transmission line is obtained.

A further object of the invention is to provide a splitter filter comprising a passive filter with a complex impedance of the above-mentioned character.

The inventive construction of the passive filter with complex impedance is made possible by certain losses being intentionally introduced into the filter. The losses contribute to making the impedance of the filter sufficiently complex to be able to match the complex impedance of a transmission line.

The invention utilizes the observation that in many situations it is acceptable with certain losses in a splitter filter. that, when in the above-mentioned U.S. patent U.S. 5,623,543, lines 61-65, the invention is further based on the observation column 3, it is found that passive 10 15 20 25 30 518 713 - - | u a u n ~. o ø o a o o u | u n n. n q. n. n. filter has resistive impedance, then the starting point must be that this filter is lossless or almost lossless.

Traditionally, resistances are not intentionally introduced into a passive filter because one wants to keep down the losses in the filter. However, the invention shows that if losses at a certain determined level can be accepted, then a deliberately introduced resistance in a passive filter can contribute to giving the filter an impedance which is complex so that good matching against the transmission line impedance can be achieved.

According to an embodiment of the invention, a filter according to the invention is constructed from a cable simulator section which simulates the filter impedance of one to which transmission line is to be connected. The cable simulator section is designed so that it also simulates the resistance of the transmission line. By adapting the cable simulator section so that it is given an improved barrier band attenuation in a desired frequency range, a passive filter with a complex impedance similar to the transmission line can be created.

A filter according to the invention has the advantage that it can be installed in a place that does not have a power supply.

Another advantage is that a filter according to the invention works even in the event of a power failure. Active elements must be powered, may be sensitive to overvoltages and may occur in self-oscillation. Since the filter according to the invention is passive, another advantage of the invention is that the above-mentioned problems with active elements can be avoided.

A filter according to the invention also has the advantage that it enables good impedance matching against a transmission line to which it is connected. In this way, problems with echo and side tones can be minimized. 10 15 20 25 518 713 a - n Q u ø o a o n n Q u n o y I ~ o Q a o | The invention will now be described in more detail by means of preferred embodiments and with reference to the accompanying drawings.

DESCRIPTION OF THE FIGURES Fig. 1 shows a circuit diagram of a circuit equivalent to an impedance multiplied inductance.

Fig. 2 shows a circuit diagram of a cable simulator section.

Fig. 3 shows a circuit diagram of a filter section according to the invention.

Fig. 4 shows a circuit diagram of a cable simulator section for the so-called ETSI impedance.

Fig. 5 shows a circuit diagram of a filter section according to the invention which is suitable for matching against the ETSI impedance.

Fig. 6 shows a circuit diagram of a part of a splitter filter illustrating a parallel connection between a low-pass filter and a high-pass filter.

Fig. 7 shows a circuit diagram of a part of a splitter filter illustrating series connection between a low-pass filter and a high-pass filter.

Fig. 8 shows a circuit diagram of an embodiment of a low-pass filter according to the invention with an extra pass band.

Fig. 9 shows a circuit diagram of an alternative embodiment of a low-pass filter according to the invention with an extra pass band.

Fig. 10 shows a circuit diagram comprising a low-pass filter according to the invention. over a splitter filter v u ...- 10 15 20 25 30 518 713 ø c n o .o n: nu n u c o o n vv n a n »| n c ø a o a.

Fig. 11 shows a detailed circuit diagram of a circuit in the splitter filter of Fig. 10.

Fig. 12 shows a circuit diagram of an alternative embodiment of a filter section according to the invention.

Fig. 13 shows a circuit diagram of a further alternative embodiment of a filter section according to the invention.

Fig. 14 shows a flow chart of a method according to the invention.

PREFERRED EMBODIMENTS As mentioned above, there are several reasons why it would be particularly advantageous to use a passive low-pass filter with a complex impedance in a splitter filter. It is desirable that the impedance of the low-pass filter provides a good match to the complex impedance of the J transmission line in order to avoid, for example, disturbing echoes and side tones. Thus, there is interest in a method of constructing a passive filter with a complex which has satisfactory impedance. impedance, impedance in a way matches a predetermined complex However, no such method is previously known. For example, U.S. Patent No. 5,623,543, lines 61-65 states that the impedance matching requirement, not column 3, can be met with passive filters as they have resistive characteristic impedance. However, the invention shows that passive filters with truly complex impedance can be constructed.

A straightforward attempt to construct a passive filter with a complex impedance is to start from a passive filter with resistive or mainly resistive impedance, which filter is lossless or has low losses. The filter used as a starting point in the design experiment is called 10 15 20 25 518 713 u u o o n | a n o Q u a n u u n u n o n Q n ~ n o e Q u n a; hereinafter the resistive filter because the filter has at least substantially resistive impedance.

The design experiment aims to, without significantly affecting the filter properties of the resistive filter, the filter that the impedance ZW convert resistive impedance so resembles a predetermined complex called here the matching impedance. the conversion attempt of the filter, from 'the resistive to so that impedance multiplication by the factor ZQ / RO on each element of that filter, impedance goes one performs a resistive the 1 where Ro is the resistance of the resistive filter. With a nominal impedance Z0 = R, + EQ, an impedance multiplication of an inductance in the resistive filter results in the following: R, + I - + s- (Q R S.L_) S.L .___ 2m_. . : ___- m Ro Ro __å __ + 'Rz-s-L L which is equivalent to a circuit section 1 shown in Fig. 1. The circuit section 1 comprises a first coil 2a with the inductor L-get connected in series. with a second coil 2b with 2 R. the inductance L--, with which second coil 2b a resistor 3 with the resistance is connected in parallel.

However, when a filter capacitance in with the factor Z0 / Ro impedance is multiplied, it does not lead to a simple equivalent case. The result is frequency-dependent negative resistance. as in when an inductance of an inductance is multiplied. instead, an impedance containing To provide such an impedance, active elements must be used and thus it is not possible to construct a passive filter with a complex impedance similar to the matching impedance with this method.

The invention enables the construction of a passive filter with a complex impedance which, when the filter is connected to a predetermined complex impedance, matches the predetermined complex impedance. The predetermined complex impedance may be a particular transmission line impedance, an impedance defined in a standard or any other impedance against which it is found appropriate to match the impedance of the filter. An example of an impedance defined in a standard is the so-called ETSI impedance 150nF // 750§2 + 270§M (ZBTSI = which is developed as a compromise between the impedances of different cable dimensions and lengths and which is often used as a matching impedance It is customary for requirements to be set for a filter for the filter to be connected to I ITU-T Draft G.992.1, requirements for attenuation and attenuation distortion at POTS and the situation where a certain specific impedance is required. in Europe, as these filters are connected to the ETSI impedance.

The embodiments presented below of the invention will mainly concern passive low-pass filters in ADSL systems as this is a particularly interesting field of application of the invention. The invention can be used to construct the filter according to the invention. However, the invention is not bound passband but the filter with different types of passband such as high-pass filter, band-pass filter and low-pass filter. A filter according to the invention is also not limited to a certain type of system.

The invention should, for example, be of interest for other types of DSL systems than ADSL, such as VDSL systems or HDSL systems.

According to the invention, the filter is given intentional losses which contribute to giving the impedance of the filter its desired complex character. In the design experiment described above, the starting point was a lossless filter with desirable filtering properties, to whose impedance becomes According to one embodiment, one then tried to change complexes corresponding to the matching impedance. of the invention, the starting point is the opposite. to first Namely construct a circuit segment with a complex impedance corresponding to the matching impedance and then construct a filter from the circuit segment by giving the circuit segment desired filtering properties.

Losses are intentionally allowed and help to give the filter the desired complex impedance. As a rule, one naturally tries to avoid losses which impair the signal transmission, but as will appear in the description of the invention, losses can in some cases be used to achieve the desired result. As mentioned, ITU-T Draft G.992.1 specifies ISDN-BA splitter filters in Europe.

Annex E requirements for POTS and The document states that an insertion attenuation of up to 1 dB at a frequency of 1 kHz to allow intentional use is accepted. This provides some room for losses and can be used for the construction of a passive filter with complex impedance.

How much space is to construct with intentional losses is of course dependent on the requirements placed on the filter's properties.

Assume that a low-pass filter is to be designed and that it is desirable that the impedance of the low-pass filter mimics as closely as possible the characteristic impedance of a transmission cable. The impedance of the transmission cable can be represented _with four parameters; the resistance, inductance, capacitance and conductance per unit length.

The conductance can mostly be neglected. The characteristic impedance of the transmission cable is + 'wl _.

Z¿m == l; # å-, where r is the resistance, l the inductance, g g + jan 10 15 20 25 30 35 513 713 §_j = s "; ° -.f fw-'z - = -" = - :: «s - s: nu nu uo oo: oacnnoc co o nu nccoaauvn 9 nou nr nu -n .nu n .. u. Ao 11 conductance, c capacitance, w angular frequency and j2 = -1.

The impedance of a certain length of the transmission cable can be simulated with a circuit section comprising discrete components. in order that several such circuit sections can be cascaded, simulating the impedance of another length of the transmission cable. An unbalanced cable simulator section 4 Fig. 2. first port 5 and a second port 6. Above the first port 5 shown in the cable simulator section 4 comprises a connected and above the second Between 8 is a resistor 9 and an inductance 10 is a first capacitor 7 port 6 is a second capacitance 8 connected. capacitances 7, connected in series. The cable simulator section 4 has a very small filter. barrier band attenuation and therefore works poorly as the cable simulator section 4: can, however, be converted into a filter section 11 by connecting a third capacitance 12 parallel to the resistor 9 and the inductance 10 as shown in Fig. 3. Alternatively, the third capacitance 12 could have been connected in parallel only with the inductance 10 The * third capacitance 12 introduces a barrier peak which improves the barrier band attenuation of the filter section 11. For a low pass filter to be used in an ADSL system, the effect of the third capacitance on the speech band is negligible due to the large frequency difference between the speech band and the barrier band. The filter section 11 is a very simple passive filter with complex impedance according to the invention.

Since the filter section 11 includes the resistance 9, the filter section 11 has intentional losses which contribute to providing good impedance matching to the complex impedance of the transmission cable.

In many cases the simple filter section 11 is not sufficient to meet the set requirements' on filter properties and By cascading a plurality of filter sections 11 it can impedance. be possible to achieve improved filter properties that can ensure that the set requirements are met. 10 15 20 25 30 35 518 713 '°° "' -: ø o» u ~ H 12 In the following, an inventive filter is described which meets the requirements of ITU-T Draft G.992.l, Annex E which is set to POTS and ISDN-BA splitter filters in Europe As mentioned above, splitter filters include a high-pass filter and a low-pass filter, impedance matching is particularly important for the low-pass filter, and ITU-T Draft G.992.l states that matching should take place against eg the ETSI impedance Zgßï = l50nF // 75052 + 270š2 Other important requirements set in the ITU-T document are to be the frequency range 500-2000 Hz. the said reflection attenuation greater than 18 dB in Below 500 Hz and above 2000 Hz reduces the requirements for the reflection attenuation. 300 Hz and (return loss) at 3400 Hz, the requirement is that the reflection attenuation must be greater than 14 dB. The insertion loss may be up to 1 dB at 1 kHz and the attenuation distortion loss distortion may be in the range 200-4000 Hz. not more than 1 dB in To construct the invention The filter that meets the requirements for Europe in ITU-T Draft G.992.l, Annex E is first constructed a cable simulator section with an impedance similar to the ETSI impedance which is then used as a basis for the Studies to ETSI- by cascading the continued filter construction. shows the impedance, cable simulator sections can be approximated comprising series elements with high resistance and small inductance for frequencies in an upper part of the speech band and with low resistance and large inductance in a lower part of the speech band. This can be achieved, for example, with a cable simulator section 13 shown in Fig. 4, which cable simulator section 13 comprises a parallel combination of a larger inductance 14 in series with a small resistance 15 and a smaller inductance 16 in series with a large resistance 17. The cable simulator section also comprises a first and a second port 5, 6 and a first and second capacitance 7, 8 corresponding to the same elements in the cable simulator section 4 as 518 713 '°' °. . I | ø ø. ø | oo 13 is shown in Fig. 2. As stated earlier, the cable simulator section 4 in Fig. 2 does not work well as. filter and also the cable simulator section 13 in Fig. 4 has little filtering effect.

Fig. 5 shows a filter section 18 based on the cable simulator section 13 in Fig. 4. The capacitance 12 has been connected in parallel with the series elements 14, 15, 16, 17 in the cable simulator section 13 in order to give greater in the corresponding manner as described in connection with Fig. 3 barrier band damping. The filter according to the invention which meets the requirements for Europe in ITU-T Draft G.992.1, Annex E can be constructed by cascading several filter sections similar to the filter section 18 in Fig. 5. However, in order to obtain as good a filter as possible, there are further some questions regarding the filter design that should be noted.

According to the prior art, the low-pass filter and the high-pass filter are usually connected in parallel in a splitter filter. The traditional parallel connection is illustrated in Fig. 6.

Fig. 6 shows a section 19 of an unbalanced ADSL splitter filter. to a Section 19 can be connected via a port 20 transmission line. A port 21 is used for connection to the POTS path in an ADSL system and a port 22 to Between the line port 20 and the POTS port 21 a low-pass filter 23 is connected. I is used for connection the ADSL path. the figure shows a coil 24 and a capacitor 25, which are components of the low-pass filter 23.

The lines marked with dashed lines indicate that the low-pass filter 23 may comprise more components than the two mentioned. In parallel with the low-pass filter 23, between the line port 20 and the ADSL port 22, a high-pass filter 26 is connected. The figure shows a capacitor 27 and a coil 28 which are components of the high-pass filter 26.

The high-pass filter may comprise more components than the capacitor 27 and the coil 28 and this is indicated by dashed lines in Fig. 6. To avoid the influence of the high-pass filter in 10 15 20 25 30 35 518 713 - e | . . '_ u °' '. . . - - ø n o o II 14 the speech band, the low-pass filter should have the high-pass filter when connected in parallel with the impedance for frequencies in the pass band of the low-pass filter. The low-pass filter should similarly have a high impedance for frequencies in the high-pass filter's passband so as not to adversely affect ADSL traffic when the low-pass filter is connected in parallel with the high-pass filter.

When connected in parallel when connected in parallel, for an ADSL splitter filter, ideal conditions are thus the properties of the filters, but in practice the high-pass filter. When connected in parallel, it is therefore necessary to take into account the large influence of capacitance on the impedance in the speech band. the impedance of the high-pass filter when designing the low-pass filter.

In telecommunication systems around the world, it has been chosen to give the POTS path a higher impedance than the characteristic impedance of a transmission cable in order to obtain as low attenuation as possible. However, the ADSL path in an ADSL system has an impedance _ characteristic impedance. The resulting aspect ratio between the impedances of the POTS paths and the ADSL close to a transmission cable means that series connection of the low-pass filter and the high-pass filter in a splitter filter is often preferable. If the low-pass filter and the high-pass filter are connected in series, the impact of the high-pass filter on the low-pass filter's performance in the speech band can be made very small. Thus, in the case of a series connection, the low-pass filter can be constructed almost independently of the high-pass filter. Although the low-pass filter strongly affects the performance of the high-pass filter in series connection, which means that this must be taken into account when designing the high-pass filter, but when designing a splitter filter comprising a passive low-pass filter with complex impedance, it is easier to take into account. on the contrary. filter meets the requirements for Europe in ITU-T Draft G.992.l, the construction of the Annex E according to the invention is thus used in series connection between the high-pass filter and the low-pass filter 10 15 20 25 30 35 518 713 15. Fig. 7 shows a series connection of a high-pass filter and a low-pass filter. The figure illustrates a section 30 of an unbalanced ADSL splitter filter. port 31 to a used for connection is connected via a A port 32 Section 30 can transmission line. to the POTS path in an ADSL system and a port 33 is used to connect to the ADSL path. A low-pass filter 34 is connected between the line port 31 and the POTS port 32. The figure shows a capacitor 35 included in the low-pass filter 34. The dashed lines to the right of the capacitor indicate that the low-pass filter may comprise more components than the said capacitor 35. Serially connected with the low-pass filter, between the line port 31 and the ADSL port 33, a high-pass filter 36 is connected . The figure shows a transformer 37, a capacitor 38 and a coil 39 which are components of the high-pass filter. It is possible that another embodiment of the high-pass filter lacks one or both of the components 38 and 39 in the high-pass filter 36. It is possible that the high-pass filter 36 comprises more components than those mentioned and this is indicated by dashed lines in Fig. 7. At the high-pass filter and the low-pass filter each filter if the series connection of the filter is achieved, little effect is achieved between small impedance in the second passband. The end of the filters towards the transmission line therefore looks different in the case of a series connection compared with a parallel connection.

In some cases, you want to send rate pulses at a frequency above the speech band, for example at 12 or 16 kHz through the low-pass filter. However, the intentionally high resistance in the filter, in order to produce the complex impedance, results in excessive attenuation of the tariff pulse frequencies. This problem can be remedied by giving the low-pass filter an extra passband.

The complex impedance and thus the high resistance is only necessary in the speech band, which means that the large resistance can be decoupled for higher frequencies. Fig. 8 shows a filter section 40 which is adapted for rate pulses.

It is also> 10 15 20 25 30 35 now II 0 '518 713 z "a' =" z '* 16 The filter section 40 is identical to the filter section 18 in Fig. 5, as if the filter section 40 has a capacitor 41 in parallel connected with the large resistance 17. The capacitor helps to disconnect the large resistance 17 at high frequencies. Another positive effect of the capacitor 17 is that it also helps to improve the similarity between the impedance of the filter section and the ETSI impedance. Further improvement in the decoupling of the large resistor 17 is obtained with a filter section 45 shown in Fig. 9. What separates the filter section 45 from the filter section 40 in Fig. 8 is a series inductance 46, which together with the capacitor 41 forms a series resonant circuit which can short circuit the large resistance 17 completely at a frequency where desired. When the frequency for which the short circuit of the large resistance is desired is determined, the element values of the series inductance 46 and the short circuit can be obtained. the capacitor 41 is selected so that the desired one, it may be necessary to make the filter sections 40, 45 more complicated so that the resistance becomes high again above the frequency for which lower resistance and an extra passband are desired. One possible way to accomplish this for the filter section 45 may be to connect an additional capacitor in parallel with the inductor 46.

Above, the filter section 18 that can be used to construct a splitter filter with a passive low-pass filter with complex impedance has been presented, which splitter filter meets the requirements for Europe in ITU-T Draft G.992.l, Annex E.

The above also has a justification as to why the high-pass filter and said splitter filter should have been given the low-pass filter in series and improvements of the filter section 18, which leads to an extra pass band for tax pulses, have been shown. Based on these lessons, the said splitter filter according to the invention, ITU-T Draft G.992.l, can be constructed in order for the splitter filter to be as good as meets the requirements for Europe in Annex E.

Depending on the requirements. 10 15 20 25 30 35 518 713 nonc- u | u n of n ... - ~. n I '° ~ »u o n ~ | rv 17 properties as possible must a compromise between i.a. barrier tape attenuation, passband attenuation, reflection attenuation and attenuation distortion are done. This can be done by allowing an optimization procedure to determine the component values of the splitter filter under the condition that the current requirements are met. Examples of suitable optimization routines are described in the Andrew Grace manual, “Optimization Toolbox For Use with, MATLAB”, Oct 1994, The Math Work Inc. and are also available in the SABER circuit analysis program.

Fig. 10 shows a splitter filter 50 which meets the requirements for Europe in ITU-T Draft G.992.1, Annex E. The splitter filter comprises a passive low-pass filter 51 with complex impedance which is connected in series to a high-pass filter 52 which is also passive. This means that the splitter filter 50 is completely passive. The low-pass filter 51 is composed of four cascaded balanced filter sections 53, 54, 55, 56 which each resemble a balanced shape of the filter section 40 in Fig. 8. Each filter section 53, 54, 55, passive with intentional losses and complex impedance.

Common to each filter section is that each of them comprises a circuit X, 11. The filter section 53 which circuit is described in detail in Fig. Comprises in addition to the circuit X a capacitor 57 with a capacitance Cf = 10 nF, two capacitors 58, 59 with a capacitance C2 = 2.7 nF, and a capacitor 60 with. a capacitance C3 = 22 nF, which capacitor is divided by the filter section 54. In addition to the components already mentioned, the filter section 54 comprises two capacitors 61, 62 with a capacitance C4 = 15 nF, and a capacitor 63 with a capacitance C5 = 15 nF, which is divided with the filter section 55.

The filter section 55 comprises, in addition to the already mentioned components, two capacitors 64, 65 C6 = 15 DF, with a capacitance and a capacitor 66 with a capacitance Cf = 12nF, which is divided by the filter section 56. The filter section 56 comprises, in addition to the already mentioned components, two capacitors 67, 68 med. a capacitance C8 = 10 nF, and a 56 is thus 10 15 20 25 30 35 518 713 g II l - '' '' ',. '. . . u | o «0- 18 capacitor 69 with a capacitance C @ = 22 nF. The high-pass filter comprises an inductor 70 with three windings.

The main inductance of the inductor is] ¿m = 500 pH. As mentioned above, the influence of the low-pass filter must be taken into account when designing the high-pass filter about the high-pass filter and thus the properties of the high-pass filter only by the inductor 70 but also the low-pass filter are connected in series. is not determined by the influence of the low-pass filter 51. 11 comprises an inductor 71 with L1 = 11, 5 mH, two The circuit X shown in Fig. two windings, with a total inductance resistors 72, 73 with a resistance Ih = 4.83 (2 , an inductor 74 with two windings, with a total inductance IQ = 5.87 mH, two resistors 75, 76 with a resistance R2 = 6.5 S2, two resistors 77, 78 with a resistance R22 = 54.5 Q, and two Cn = 680 nF. 73, 75 and 76 are completely or partially replaced by winding resistors in and 74. capacitors 79, 80 with capacitance Alternatively, the resistors 72, the inductors 71 The splitter filter 50 can be designed to first, as described above, construct a filter section which is passive with complex impedance similar to the ETSI impedance.This filter section has then been used as a base for the low-pass filter 51 in the splitter filter.Then the element values have been optimized given the set requirements for the filter properties.In this case the set requirements include the requirements specified for Europe in ITU-T Draft G.992.l, Annex E. These requirements cannot be achieved with only one filter section in the low-pass filter. When cascading four, however, the result is the splitter filter 51 with the element values as sections, it is possible to achieve the requirements and described in connection with the descriptions of Figs. 10 and 11.

Probably even better results could be achieved if more than four sections were cascaded. In the splitter filter 51, 10 15 20 25 30 35 518 713 ac. _ nu o n. 19 structurally identical filter sections are cascaded, but it is also possible according to the invention to construct a passive low-pass filter with complex impedance which is composed of a plurality of structurally different filter sections.

In this context, structurally identical sections are meant sections whose circuit diagram looks identical, but whose constituent components may have different element values. By structurally different sections is thus meant sections whose circuit diagram looks different.

It is not necessary according to the invention that all cascade-coupled filter sections have intentional losses.

The invention only assumes that intentional losses in the low-pass filter as a whole contribute to giving the filter its characteristic complex impedance. Thus, according to the invention, it is possible to combine an intentional loss with a filter section without intentional losses for the construction of a filter according to the invention.

Above, a pair of filter sections according to the invention have been described. Within the scope of the invention, a very large number of alternative filter sections are possible. A further couple of alternative embodiments of alternative filter sections are described below with reference to figures.

Common to all the filter sections according to the invention is that they are passive with a truly complex impedance and that each of the filter sections comprises at least one resistance which contributes to producing the truly complex impedance of the filter section.

Fig. 12 alternatively shows an embodiment of a filter section 90 according to the invention. The filter section 90 is an alternative to the filter section 18 which was described in filter section with 518 713 518 713,, n o n o a o o 0. . o 0 nu; I '° U' _ I,. . . connection to Fig. 5 and is, like the filter section 18, adapted to be a suitable building block in a filter to be matched to the said ETSI impedance.

The filter section 90 comprises a first and a second port 5, 6, a capacitor 91, and a capacitor 92. Furthermore, the filter section 90 comprises a relatively small resistance 93 in series with a relatively small inductance 94 and a relatively large resistance 95 in parallel with a relatively large inductance 96. A capacitor 97 provides the filter section with blocking peaks which improve the filtering effect of the filter section.

Another alternative embodiment of a filter section 100 according to the invention is shown in Figure 13. With the filter section 100 similar properties can be obtained as with the filter section 11 in Fig. 3. The filter section 100 comprises a first and a second port 5, 6, two capacitors 101, 102, a resistor 103 and a coupling coil 105. The coupling coil gives the filter section 100 a blocking peak in the same way as the capacitor 12 in Fig. 3. shows all unbalanced Figures 2-9, 12 and 13 embodiments. In practice, however, balanced equivalents are most common. The invention is of course not limited to any balanced or unbalanced form. It is to be understood that embodiments are to be understood as meaning that all presented balanced or unbalanced equivalents are encompassed by the invention.

From the description, with reference to the figures of different embodiments of devices according to the invention, it has appeared indirectly how a method according to the invention for constructing passive filters with complex impedance can be designed. To further clarify an inventive method, a flow chart of an embodiment of Fig. 14 is illustrated. The method described in Fig. 14 is an inventive method of constructing a splitter filter comprising a passive filter. low-pass filters with a 110 identify the requirements for attenuation (eg barrier attenuation and truly complex impedance. In the first stage reflection attenuation) and attenuation distortion, which you want the splitter filter to meet. In connection with this, the complex impedance against which the filter is to be matched is also determined. In a next step 111, a cable simulator section with an impedance close to the matching impedance is constructed from the matching impedance. This cable simulator section is modified to a filter section, step 112, by means of a parallel capacitor which improves, for example, a parallel capacitor which introduces barrier peaks in the barrier band. The filter section acts as a first approach to a low-pass filter in the splitter filter.

Depending on what the requirements are to be met and how much knowledge and experience there is of filter design, it can be advantageous to make an estimate of the minimum number of cascade-connected filter sections required step 118. In cases where it is known that the requirements can be met with less than where one to the number to meet the set requirements, filter sections the certain number is made the attempt at least that the low-pass filter with estimated Missing for step 118 filter sections. knowledge make an estimate in so a filter section is used in the approach.

In this case, when a splitter filter is to be designed, to a suitably series connected to the low-pass filter, step 113. Then a batch high-pass filter must be made as this example mainly concerns low-pass filter construction, the construction of the high-pass filter part of the splitter filter is not described in more detail.

In a next step 114, the element values for the first charge of the splitter filter are optimized from the set up. vv U "": uno 5'18 IIS '°: ". :: ßnß fl ---:' â fifl --- 7..... ...... ;;: 2 ....._- ;;;.

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,,. ». . IC 22 requirements. After the element values have been determined, it is checked whether it was possible to achieve the set requirements with a splitter filter with a current structure, step 115. If the requirements could not be met, the low-pass filter is extended by cascading to step 116. as mentioned above, another filter section original filter section , This additional filter section may, be structurally different.

Then the optimization of the element values is repeated, step 114. identical to the first or structurally If the set requirements could be met, the construction on the paper of the splitter filter is ready and the filter is ready to be realized based on the developed construction.

In steps 114, 115 and 116, it is the low-pass filter and the set requirements for the low-pass filter that are in focus as it is mainly low-pass filter construction that the example touches on.

Special measures to adapt the high-pass filter part of the splitter filter may be necessary, but these are not discussed further here.

The central point of an inventive method for constructing a passive filter with truly complex impedance is that, of course, only passive components are used and that resistances are introduced to give the filter the truly complex impedance that is desirable in terms of measurement. In the method described in Fig. 14, said resistance is introduced which helps to give the filter its complex impedance in step 111 in that the cable simulator section comprises the resistance of a cable with the matching impedance.

Different vary greatly. embodiments of an inventive method The inventive method of Fig. 14 was intended for the construction of a splitter filter in which a passive low-pass filter with complex impedance was a component. In some cases, the design of a complete splitter filter may not be the goal, but you may want to 10 15 20 518 713. ~: 1 =; ==; use a method for the construction of passive filter sections with complex impedance that can later be used as building blocks in the construction of a finished splitter filter.

The knowledge that certain allowable losses can provide space for designing with, intentional losses and genon1 these can bring about truly complex impedance of a passive filter, may provide the possibility to deviate from the order of steps described in the method in Fig. 14. With this knowledge, it may be possible to adapt existing passive filters with mainly resistive impedance so that they have a more complex impedance. This can be done by introducing extra resistance in the filter, for example by means of connection of a resistor or that coils with intentionally high resistance in this case one to use methodically. In the filter, the filter is provided according to the invention without going through the steps of first producing a circuit with the desired complex impedance and then adapting the filter properties of the circuit. Thus, according to the invention, it is not necessary that all the steps in Fig. 14 are performed in a method according to the invention or that the steps are performed in any particular order.

Claims (1)

A filter (11, 18, 40, 45, 51, 90, 100) for signal filtering in a telecommunication system and for impedance matching against a predetermined complex impedance, which filter has at least a first passband, characterized in that the filter is passive and that the characteristic impedance of the filter is complex so that it at least approximately matches the predetermined complex impedance; and in that a resistance (9, 15, 17, 72, 73, 75, 76, 77, 78, 93, 95, 103) of at least one of the components of the filter is selected so that the resistance contributes to giving the characteristic impedance of the filter its complex character. A filter according to claim 1, the core of at least one resistor (9, 15, 17, 72, 73, 75, 76, 77, 78, 93, 103) is in series with at least one inductance (10, 14, 16, 71, 74, 94, 105), which resistance and inductance contribute to give the filter its said complex characteristic impedance. A filter according to claim 2, characterized in that the filter comprises at least one parallel combination of a first inductance (14, 71) in series with a first resistor (15, 72, 73) and a second inductance (16, 74) in series with a second resistance (17, 75, 76, 77, 78) which first inductance is large relative to the second inductance and which first resistance is small relative to the second resistance. A filter according to claim 3, characterized in that the filter comprises at least two circuit segments (53, 54, 55, 56), of which at least one circuit segment comprises the said parallel combination. 5 15 20 25 30 10. A filter according to claim 4, characterized in that the circuit segments are four structurally identical circuit segments (53, 54, 55, 56). A filter according to claim 2, characterized in that the filter comprises at least one series combination of one (94) in series with a first resistance (96) which first inductance is small in the first inductance (93) and a second second resistance (95) relative to first resistance is small relative to the second inductance parallel to one the second inductance and which the resistance. A filter according to any one of claims 1, 2, 3 or 6, wherein the filter comprises at least (53, 54, 55, 56) the circuit segment typically comprises two cascaded circuit segments the aV which at least one at least one resistance which contributes to giving the filter characteristic impedance its said complex nature. A filter according to any one of claims 1-7, characterized in that the characteristic impedance (9, 15, 17, 72, 73, 75, 76, 77, 78, 93, 95, 103) of the filter is its said complex which contributes to character consists of at least one resistor. the filter (9, 15, A filter slightly 1-7, 72, according to characterized in that the resistance 17, 73, 75, 76, 93, 103) which contributes to giving the characteristic impedance of the filter its said complex character consists of at least one winding resistance in an inductor. A filter according to any one of claims 1-9, characterized in that the predetermined complex impedance is the characteristic impedance of a transmission line. 10 15 20 25 30 11. 12. 13. 14. 15. 51 3 713 26 A filter according to any one of claims 1-9, characterized in that the predetermined complex impedance is the ETSI impedance ZENI = 150nF // 7509 + 27OQ . A filter according to any one of claims 1 to 11, characterized in that the filter comprises at least one cable simulator section (4, 13) which cable simulator section has a characteristic impedance which at least approximately matches the predetermined complex impedance, and that the filter also comprises at least one capacitor (12 , 58, 59, 61, 62, 64, 65, 67, 68, 97), which capacitor in cooperation with the cable simulator section contributes to giving the filter at least one blocking peak in a predetermined frequency range. A filter according to any one of claims 1-11, the core simulator section (4, 13) which cable simulator section has a characteristic impedance which at least approximately matches the predetermined complex impedance, and that the filter comprises at least one coupling coil (105), which coupling coil comprises a inductance in the cable simulator section and helps to provide the filter with at least one blocking peak in a predetermined frequency range. A filter requirements 1-13, characterized in that the filter is a low-pass filter. according to any one of a filter according to any one of claims 1-14, characterized in that the filter has a further passband in a predetermined frequency range, which further passband differs from said at least first passband. 10 15 20 25 30 16. 17. 18. 19. 20. 21. 518 71 s Ií-ILEE; A splitter filter (50) comprising at least one filter according to any one of claims 1-15. A splitter filter according to claim 16, wherein the filter according to claims 1-15 is one (51) mentioned according to a low-pass filter, and that the low-pass filter is connected in series to a high-pass filter (52). A method of constructing a filter, which filter is intended for signal filtering in a telecommunication system and for impedance matching against a predetermined complex impedance, which method comprises the steps of selecting the complex impedance against which the characteristic impedance of the filter is to be matched (110): providing the filter with at least a first passband, characterized in that only passive components are used in the method and that the method also comprises the steps, (4, 13) characteristic impedance at least approximately matches it to construct a cable simulator section whose predetermined complex impedance (111), and to create the filter of the cable simulator section by adapting the cable simulator section so that it obtains at least one ratchet peak in a predetermined frequency range (112). A method according to claim 18, characterized in that a capacitor (12, 58, 59, 61, 62, 64, 65, 67, 68, 97) to the cable simulator section contributes to creating said at least one barrier peak. SOITI is connected to A method according to claim 18, characterized in that a cable simulator section is realized with a (105) creating the said at least one barrier peak. inductance in the coupling coil, which coupling coil contributes to 18-20, the core being required by the filter being provided with at least one method according to any one of claims 10 15 20 25 30 22. 23. 24. 25. 518 713,. ,. ø n. 28 a resistance (9, 15, 17, 72, 73, 75, 76, 77, 78, 93, 103) in series with at least one inductance (10, 14, 16, 71, 74, 94, 105) , which help to give the filter its said complex characteristic impedance. A method for constructing a filter, which filter is intended for signal filtering in a telecommunication system and for impedance matching against a predetermined complex impedance, in which method the filter is at least first to be provided with passband, characterized by only passive components used in the network method and that the net method comprises the step of selecting (9, 15, 17, 72, 73, 75, the filter, which resistor introduces at least one resistor 76, 77, 78, 93, 95, 103) so as to contribute to giving the filter a complex characteristic impedance that at least approximately matches the predetermined complex impedance. A method according to claim 22, characterized by at least one resistance (9, 15, 17, 72, 73, 75, 76, 77, 78, 93, 103) is in series with at least one inductance (10, 14, 16 , 71, 74, 94, 105), which resistance and inductance contribute to giving the filter its said complex characteristic impedance. claims 21-23, characterized (9, 15, 17, 72, 73, 75, 76, 77, 78, 93, 95, 103), which contribute to providing a method according to any one of the resistive filters of said complex. characteristic impedance, is realized by means of at least one resistor. claims 21-23, (9, 15, 17, 72, which contribute to giving the filter A method according to any one of the resistors 103), complex characterized 73, 75, 76, 93, its said characteristic impedance, 10 15 20 25 26. 27. 28. 29. 30. 31. 31. 518 713 29 is realized by means of at least one winding resistance of an inductance. A method according to any one of claims 18-25, core1: ec1 a parallel combination of a first inductance (14, 71) in series with a first resistance (15, 72, 73) and a second inductance (16, 74) (17, 75 , 76, 77, 78) relative to in series with a second resistance which first inductance is large in the second inductance and which first resistance is small in relation to the second resistance. A method according to claim 26, characterized in that the filter is composed of at least two circuit segments (53, 54, 55, 56), of which at least one circuit segment comprises the said parallel combination. A method according to claim 27, characterized in that the circuit segments are four structurally identical circuit segments (53, 54, 55, 56). A method according to any one of claims 18-25, core1: ec] a series combination of a first inductance (94) in series with a first resistance (93) and a second inductance (96) parallel to a second resistance (95) which first inductance is small relative to the second inductance and which first resistance is small relative to the second resistance. A method according to any one of claims 18-29, wherein the filter is a low pass filter. A method according to any one of claims 18-30, characterized in that the predetermined complex 10 15 20 25 30 32. 33. 34. 35. 36. 37. 5 1 8 71 3 Éï: ~ 30 impedance is the characteristic impedance of a transmission line. A method according to any one of claims 18-30, characterized in that the predetermined complex impedance is the ETSI impedance Zmg; = 150nF // 750Q + 270Q. A method according to any one of claims 18-32, characterized in that the method also comprises the step of optimizing the element values of the filter components on the basis of established requirements for the properties of the filter (114). A method according to claim 33, characterized in that the method also comprises an iteration procedure (114, 115, 116) where the step of optimizing the element values (114) is repeated until the set requirements are met and where for each iteration a circuit segment is added and cascaded with the previous one. the filter assembly (116). A method according to claim 34, characterized in that the method comprises a step (118) of estimating a minimum number of circuit segments for which the set requirements can be met, and in that a filter with said minimum number of circuit segments is used in the optimization step at the start of the iteration procedure. A method according to any one of claims 18-35, comprising a passband in a predetermined frequency range, which further passband differs from the at least one first passband. A method of constructing a splitter filter (50) comprising a high-pass filter and a low-pass filter, characterized in that at least one of the filters 38. 518 713 31 - ø n «. A method according to any one of claims 18 to 36. A method according to claim 37, characterized in that at least one of the filters constructed according to any one of claims 18-36 is the low-pass filter (51), and that the low-pass filter ( 51) is connected serially to the high-pass filter (52). n o. uu-