SE435121B - PHONE PAD LAYER FILTER - Google Patents

Description

lo n_ 'w 40 7903088-8 is reduced in relation to the number of components in known filters and which no longer requires any adaptation step.

A further object of the invention is to provide a low pass filter with a frequency curve which is less sensitive to temperature variations than the frequency curves of known filters.

The above-mentioned objects are achieved in that the low-pass filter according to the invention has obtained the characteristics stated in claim 1.

The low-pass filter according to the invention comprises two series-connected sections, each of which comprises an operational amplifier and of which a first section of the low-pass type has a frequency curve which asymptotically approaches a straight line with a slope of at least six decibels per octave, and a high impedance, and a second section consists of a second-order asymmetric blocking network with Cauer frequency characteristics.

The low-pass filter according to the invention has a high input impedance under certain conditions (R4C >> 125-10-6 as will appear below), so that no adjustment step is required anymore.

Further features and advantages of the invention will become apparent from the following description of an exemplary embodiment, which is illustrated in the accompanying drawing. Pig. I in the drawing shows a low-pass filter according to the invention with two sections and Fig. 2. In Fig. 1, B denotes an input terminal, I a sampling switch, schematically represented in the form of a switch, and shows the frequency curve for the second filter section.

C a capacitor connected to ground. Between the capacitor C and an output terminal S, a receiving low-pass filter according to the invention is arranged, which consists of two sections 1 and 2.

Sample switch I is closed for two microseconds every 120 ps.

A resistor R1 connects the capacitor C to a positive input of an amplifier A1 which is constituted by an operational amplifier.

Said positive input is connected to ground via a resistor H2 which is connected in parallel with a capacitor C1. A negative input on the amplifier A1 is partly connected to ground via a resistor R3 and partly connected to the output of the amplifier A1 via a resistor Ru which is connected in parallel with a capacitor C2. The components lying between the capacitor C and the output of the amplifier A1 constitute the first section of the filter 1.

Between the output of the amplifier A1 and the output terminal S of the filter, a double T-bridge and an operational amplifier A2 are connected, which device constitutes a second-order asymmetric blocking network with Cauer frequency characteristics.

Between the output of the amplifier A1 and the positive input of the amplifier A2, two capacitors C3 and Cu and two resistors RS and R6 are connected in series. A common point for the capacitors C3 and Cu is connected via a resistor R7 to the output of the amplifier A2. A common point for the resistors R5 and RB is connected via a capacitor CS to the output of the amplifier A2. The amplifier A2 has a capacitor CB connected in parallel with this resistor. Amplifier-positive input is connected to ground via a resistor R8 and the negative input of cleaner A2 is partly connected to ground via a resistor P40 and partly connected to the output of amplifier A2 via a resistor RQ. Resistors R5, RE, R? and the capacitors CQ, Cu, C form the double T-bridge.

The capacitor C at the input of the filter, which capacitor is also found at the input of known reception filters, and the resistor R1 has values which satisfy the relationship R1C >> 125-10-5, ie the time constant R1C is very large in relation to the Iam frequency 125 ps , which corresponds to the switching frequency of the sampling switch I.

V1, V2, V3, Vu, V5 denote the voltages between earth and the following points: the input terminal E, the common point of the capacitor C and the resistor R1, the positive input of the amplifier A1, the output of the amplifier A1 and the filter, respectively. output terminal S. The first filter section comprises a first filter device consisting of the resistors R1, R2 and the capacitor C1 and a second filter device consisting of the amplifier A1, the resistors R3, R and the capacitor C2.

U The first filter device has the transfer function: EM, - ___1____ V2 1 1 + al p 32 'In this connection, G1 = D + R' “1 2 a = R1 R2 Ci 1 R1 + R2 The second filter device has the transfer function: <2 - E = G 1 + azp V3 2 1 + bzp 7903088-8 RRI this relation is G = -ê-jÄ ~ Jï-, 2 R3 a _ R Ru C2 2 '+ Ru b2 = Ru C2 É The transfer function for the first filter section is of the product of the transfer functions of the first and the second filter device: ïgzïë fl ïg = gi + ag <1) V2 V2 V3 1 + bp + cpz where G = G1 G2 â = a2 b = al + b2 c = al bz such as 2 2 V3 Ã ..: ._ É ....__. 2 (2) Tf '= G (1-cw2) 2 + b2 fl ~> The relation (2) expresses the amplification, or attenuation, a function of the frequency; the corresponding curve has an asymptote with a slope of '6 dB per octave.

The second filter section has the transfer function: a _ 1 + 2-5: i, G3 ___ “i'p ___._.____ 2, 4 1 + a31åg + b3 reach? : ii E ii = G3 (u) 7903088-8 In the relation (M) it holds that: _ P is the gain or attenuation at the direct current drop, a coefficient is inversely proportional to the Q value, on which the waveform depends, the ratio represents Gao 'gain at very high frequencies the curve according to the relationship (4) has an asymptote given by the right lt fi a SO / ba; O is infinite.

Feet. 2 shows two curves given by the connection (4). In this figure, a and b correspond to two different values of the coefficient ag, the curve a having a higher Q value than the curve b.

The capacitor C, to the terminals of which the first section 1 represents the angular velocity to which the attenuation is connected, gives between the voltages V2 and V1; in the case that R1C is very large in relation to 125-10-6, the ratio. sin (-51-) få = ___._..... 2 f ° (s) V1 ___ 2 fo where fo = 8000 Hz, where fo is the sampling frequency of the received signal. In the case that in the reception filter consisting of sections 1 and 2, the second section has a frequency curve such as curve a, a correction of the term ÄU Sin ul introduced by the sampling is made possible. Faith The number of components required for realizing the filter according to Fig. 1 is much smaller than that required of known reception low-pass filters, which comprise at least four operational amplifiers. As a result, in addition to being cheaper, the filter according to the invention is less sensitive to temperature variations than known filters. In other words, its frequency curve vsezoss-a is more stable as a function of temperature, which represents a non-negligible advantage over known filters.

The invention has been described above by means of an exemplary embodiment shown in Fig. 1. It should be noted that each section can be replaced by an equivalent section. As mentioned above, the first section exhibits an attenuation of at least 6 dB_per octave at high frequencies, so a section with an attenuation higher than 6 dB per octave can be used. Correspondingly, the second section constitutes a second-order asymmetric blocking network with Camer frequency characteristics, so that within the scope of the invention the device consisting of the double T-bridge and the operational amplifier A2 can be replaced by another device having a identical transfer function.

Claims (2)

-v--, 7 7993088-8 Claim 1 1. I. Thigh pass filters for telephony purposes, characterized in that it comprises two series-connected sections (1, 2), each of which includes an operational amplifier (A1, A2); that the first section (1) is of the low-pass type with a frequency curve which asymptotically approaches a straight line with a slope of at least 6 dB / octave, and with a high impedance formed partly by a first resistor (R1) connected to a positive input terminal of the operational amplifier (Al) of the first section, partly by a capacitor (C) connected between the positive input terminal and ground; and that the second section (2) consists of a second-order asymmetric blocking network with Cauer frequency characteristics. Low-pass filter according to claim 1, characterized in that the first section (1) comprises two series-connected filter devices, of which the first device comprises the first resistor (B1), the capacitor (C) and a second, with the capacitor (C) a parallel-connected resistor (R2) which together with the first resistor (RI) forms a resistive voltage divider, and that the second filter device comprises the operational amplifier (A1), the negative-input terminal of which is connected partly to ground via a three-resistor (RB), partly to the output terminal of the operational amplifier via a parallel connection of a fourth resistor (Ru) and an additional capacitor (G2).