CS205351B1 - Integrated active filtre - Google Patents

Description

CZECHOSLOVAK SOCIALIST REPUBLIC (W) DESCRIPTION OF THE INVENTION FOR COPYRIGHT CERTIFICATION 20 (5351 (11) (Bl) (51) Int Cl.3 H 03 H 7/00 (22) Enlisted 17 01 78 (21) (PV 312—78) ORDER FOR INVENTIONS AND DISCOVERIES (40) Posted'31 03 80 (45) Published 30 03 80 (75)

Author of the invention HIRŠL JINDŘICH ing., Hradec Králové, HRUBÝ JAROSLAV ing. CSc.a NOVOTNÝ VLADIMÍR ing., Praha (54) Integrated Active Filter 1

The invention relates to integrated RC active filters with amplifiers, in particular to those which implement the second order transmission functions.

There are two ways in which integrated active filters can be produced Sometimes produced as a customer-specific filter characterized by the n-thrust transfer function As the only usually hybrid integrated circuit. Both active and passive elements are formed on the substrate, and passive elements are set to the desired values by a suitable process. The problem is the considerable variability of filter requirements. Thus, only filters which are used in large series can be produced economically. Therefore, the ability to decompose complex transmission functions is a combination of simpler types of partial transfer functions. This approach is then led by the production of so-called selective standardized function blocks. These function blocks are actually elementary filters with transfer functions usually of the second order. Function blocks are designed to allow the realization of some of the basic types of sub-transfer functions, for example, lower, upper, and band-pass filters, or general biquadratic functions. From these blocks, jdepotom by various methods, in a basically two-way way, to create more complex filters with higher order transfer functions. Obviously, if the requirements for the resulting filter can be fulfilled by the second order function, the link of the function block coincides with the term wholefilter. For this reason, the term "active filter" is often used for function blocks.

Depending on the method of production and use, function blocks can be divided into so-called customer types, so-called customer types. universal types and types whose para- meters are set in certain value ranges. Customer Function Blocks, as well as the aforementioned customer-specific filters, are supplied with parameters according to customer specification such as Single Integrated Circuit. Customers are most comfortable with their use, since these function blocks or the entire filters do not need any external elements for their operation or need to be adjusted by the customer. However, the preparation of customer-type production is lengthy and naturally costly. In sera below 5,000 units per year, customer functional block delivery times and delivery times are usually unacceptable. the universal function blocks are designed so that their parameters, possibly the type of transmission functions, are possible; to establish the widest possible range of attachment of external passive elements. Without 205351 <? ií 'i? π 2053S1 / 3 body, external elements, are not common capability functions. The advantage is that these filters can be produced cheaply, in large batches, because a few types of these so-called universal functional blobs allow to cover a very wide range of filter requirements. The disadvantage is the necessity of using additional elements which increase the dimensions of the filters, increase the laboriousness and affect the stabilizers, and the fact that the external elements have to be set very precisely is greatly impaired. This causes a lot of trouble for the customer circle, which is the universal type, because these customers are usually not - exactly set up - technically equipped. The versatile usability of these types is hampered by serious shortcomings. Some manufacturers are looking for a certain .com-promising solution between customer and universal function blocks by producing blobs whose parameters are set, in certain value rows. Since these parameters are at least the critical frequency f0, the quality factor Q, and possibly the type of transfer function of the function blocks, it is clear that the requirement of covering the requirements area in this way leads to a large and confusing range of products, which in turn reduces seriality achieved for individual types. Of course, this is also adversely affected. In addition, it is often the case that the standardized product, by its parameters, which does not meet the specific requirements of the customer, which then has to use the external finishing elements, also results, though to a lesser extent, in the problems already mentioned with the universal functional blocks.

Many of these drawbacks are eliminated by the integrated active filter according to the invention, carrying out the second order transfer function consisting of a circuit structure with three inverting amplifiers, one separating amplifier, at least two capacitors, and at least six resistors, two1 condensers are connected. the input and output of the two inverting amplifiers, one resistor is connected to the intermediate input and the output of the remaining amplifier, the three resistors always connect the output of one of the inverting amplifiers, with the following inverting amplifier, one of the resistors is parallel connected to one of the capacitors, one from the resistors, the input of the filter with the input of one of the inverting amplifiers and the input of the separating amplifier is connected by a filter outlet, all the inverting amplifiers and the separating amplifier being built into a single, integrated circuit to which the outlets are fed and the inputs of all amplifiers, which consist in the fact that at least one of the terminals of the integrated circuit is connected by at least six outlets from another integrated circuit; this integrated circuit comprises three series-connected resistors, each of which three resistors are connected to the same outlet; integrated water. \ t with the same integrated circuit, the two nodes between the two pairs of resistors are connected, with at least the other two resistors being embedded in the said integrated circuit, the ends of which are supplied to separate terminals of the same integrated. circuit.

According to the invention, one end of a series of connected three resistors can also be connected to the output of the first inverting amplifier - the other end of said triple is connected to the other inverting amplifier, the node between the first pair of resistors connected to the input of the remaining inverting amplifier and the node connecting the other pair of resistors is, associated with the output of the same inverting amplifier.

The integrated circuits constituting the active filter may be a layer or monolithic technology, but it is particularly preferred that the integrated circuit comprising only the passive elements be made of one of the layers. technology, especially thin or thick technology. It is further possible for capacitors that connect the input and output of the inverting amplifiers to be either integrated into the integrated circuit with resistors, or contained in another separate integrated circuit. These capacitors can also be connected to an integrated circuit with amplifiers as external discrete elements.

The integrated active filter according to the invention has a number of advantageous properties. An integrated circuit incorporating amplifiers is uniform for a very wide range of parameters and types of transfer functions. Therefore, a manufacturer can produce a universal component in large serials and its price will be low. The integrated circuit, or circuitry determining the transmission function, is simple and contains only passive elements. In manufacturing, the passive element parameters can be greatly improved and stabilized using such technological operations that would damage or destroy the active elements. For example, it is possible to use two-phase resistance calibrations and to subject the circuits to thermal cycles. Resistors do not form closed loops, so they can be easily measured and calibrated without the hassle and risk of existing active filters. In some cases, it is preferable to split the passive part into two; integrated circuits. Indeed, the resistive structure can be realized by thin-film technology, which further improves the parameters.

Due to the simplicity and ease of calibrability of the passive part, determining parameters 205351

The transfer function can be easily modified to meet specific requirements. The above-mentioned facts make it possible to overcome the most serious disadvantage of existing embodiments of customer active filters. In fact, the integrated active filters according to the invention can be produced economically even in series from 100 pcs. However, according to the invention, it is also possible to produce active filters of the universal type and of the type-graded in the value series. Advantageously, it is also possible to produce filters in which several passive parts can be connected to one active part and so on. economically, change the transfer function. Exemplary embodiments of the active filters according to the invention are shown schematically in the drawings, in which Fig. 1 shows an embodiment of an active low-pass filter. Fig. 2 is an active filter implementing a high pass filter; Fig. 3 is an active bandpass filter; Fig. 4 is an integrated circuit including two resistors and two capacitors and Fig. 5 is an integrated circuit containing complete passive part of the RC. An example of a possible embodiment of the low pass according to the invention is in Fig. 1. second rejection 4, third resistance. 5, the fourth resistor 6 and the fifth resistor 7 are integrated in the integrated circuit 9 and in the second integrated circuit 1 the first inverting amplifier is the first. 10, the second inverting amplifier 11 is the third inverting amplifier 12 and the decoupling amplifier 13. The signal is fed to the input terminal 2, the output signal is taken from the output terminal 8 connected to the output of the separation. The amplifier 13, the input terminal 2, is the first resistor 3 connected to the input of the first, inverting amplifier 10, which is connected via the fifth resistor 7 to the output of the third inverting amplifier 12. The output of the first inverting amplifier 10 is connected via the second resistor 4 to the input of the second inverting amplifier 11, between which, the third resistor is connected to the "output". 5. The output of the second inverting amplifier 11 is the dummy fourth resistor 6 coupled to the input of the third inverting amplifier 12. Between the input of the first inverting amplifier 10, a damping resistor 16 is connected in parallel with the first condenser 14. There is a second capacitor between the input and output of the third inverting amplifier 12 15. An output amplifier 13 is connected to the output of the third inverting amplifier 12. The first capacitor 14, the capacitor 15 and the capacitor 16 are discrete components connected outside the integrated circuits. An example of a possible embodiment of the upper permeability of the invention is shown in Fig. 2. The integrated circuits 1 and 3 correspond to the integrated circuits of Fig. 1; l .: The input signal is again applied to the input terminal 2, the output signal is taken from the output terminal 8 connected by the isolation output; The input terminal 2 is connected via the resistor 3 to the input of the second amplifier 11 and via the resistor 17 via the input of the first amplifier 10, which is connected via the resistor 7 to the output of the third amplifier 12. with the input of the amplifier 11. The input and output of the first amplifier 10 are connected in parallel with the resistor 16a of the capacitor 14, a resistor 5 is connected between the input and output of the second amplifier 11, a capacitor 15 is connected between the input and output of the third amplifier 12 The output of the second amplifier 11 is coupled to the input of the amplifier 13 and through the resistor 6 to the input of the third amplifier 12. The capacitors 14a and the resistors 16 and 17 are discrete components connected outside to the integrated circuits. An example of a possible realization of the bandpass according to the invention is shown in Fig. 3. The embodiment completely coincides with the embodiment of the low pass filter of Fig. 1 except that the input of the splitter 13 is instead of the output of the third silencer 12 connected to the output of the second emitter 11.

Fig. 4 is an integrated circuit 101 comprising capacitors 114 and 115 and resistors 116 and 117. Integrated capacitors 114 and 115 and resistors. 116 and 117 correspond to the electrical discrete capacitors 14 and 1.5 and the pores 16 and 17 of the embodiments of the active filters according to FIGS. 1, 2, and 3, using integrated circuits 1, 9 a. 1, 2, 3 and 3, except that the discrete resistors 16 and 17 can be formed again with an electrical connection identical to those shown in FIGS. and capacitors 14 and 15 are replaced by resistors 116 and 117 and capacitors 114 and 115 integrated, in circuit 101, respectively.

Fig. 5 shows an integrated circuit 201. comprising resistors 203, 204, 205, 206,207, 216, 217 and capacitors 214a, 215, electrically. it corresponds to the discrete resistances, .3, 4, 5, 6, 7, 16, 17 and the capacitors 14 and 15 of the exemplary embodiments of the active filters, respectively. 1, 2 and 3. The integrated circuit 201 is provided with terminals 31, 32, 33, 34, 35, 36, 37, 38, 39. The resistor 203 is connected between terminals 31 and 32, respectively. resistor 204 between terminals 35 and 36, resistance 205 between terminals 36 and 37, resistor 206 between terminals 37 and 38, resistor 207 between terminals 34 and 39, resistor 216 between terminals 34 and 35, resistor 217 between terminals 33 and 34 , a capacitor 214 between the outlets 34 and 35 and a condenser 215 between the outlets 38 and 39. Using the integrated circuits 1 and 201, a lower, high pass filter can be created again without discrete elements.

Claims (2)

205351 7 according to the examples shown in Figs. 1, 2 and 3 to "that resistors 3,4 / 5, 6, 7, 16 and 17 are interrupted by resistors 203, 204, 205, 206, 207,216 and 217 integrated in circuit 201 and the individual capacitors 14 and 15 are replaced by capacitors 214 and 215 integrated in the circuit 201. The operation of the filter according to the invention can be explained by the example of the low-pass filter shown in FIG. 1. The active filter comprises two integrators and one inverter connected in a cascade in a closed feedback loop. The feedback effect is created by a pair of complex coupled poles of the transfer function. The amplifiers needed to form the integrators and the inverter as well as the amplifier that serves to impedance separation of the loop output from the load form an active part of the filter and are formed in the integrated circuit 1. The passive part of the filter contains elements co-forming integrators and inverter and specifying the transfer function's parameters. Five resistors 3.4, 5, 6, 7 of the passive part are integrated in the circuit 9. One integrator is created with a pre-set. 1. An integrated active filter implementing a 2nd order overload function consisting of a circuit structure with three inverting amplifiers, one separator amplifier, at least two capacitors, and at least six resistors, wherein two capacitors connect the input to the output of two inverting amplifiers; and the output of the remaining amplifier, the three resistors always combine the output of one of the inverting amplifiers with the following inverting amplifier, one of the resistors is connected in parallel to one of the capacitors, one of the resistors connects the input of the filter to the input of one of the inverting amplifiers and the input of the separator the amplifier is coupled to the filter output, wherein all the inverting amplifiers and the diverting amplifier are built into a single integrated circuit to which all amplifiers outputs and inputs are provided, characterized in that at least six outlets of said in The integrated circuit (1) is connected to at least six outlets from another integrated circuit (9), this integer 8 using an amplifier 10, resistors 7 and 16 and a capacitor 14. The second integrator is formed by a power amplifier 12, a resistor. 6 and a condenser 15. The inverter is provided by the amplifier 11 and the resistors 4 and 5, the input signal is supplied from the input terminal 2 via a resistor, 3 to the input of the amplifier 10, the output signal is taken off the feedback loop via the divider amplifier 13 connected to the output of the amplifier. and the output terminal output 8. Quality factor Q and the critical frequency f0 of the transfer function associated with the resistances 4, 5, 6, 7, 16 and the capacitors 14 and 15. These examples do not exhaust all possible variants of the integrated active filters according to the invention. Both passive and active parts combine with great variability and thus create diverse. required filter types. The integrated active filter according to the invention is intended for telecommunications technology, but can be used wherever they use electric frequency filters. . The circuit comprises three interconnecting resistors 4, 5 and 6), both ends of the triple conductor connected to the terminals of the same integrated circuit, and both nodes between the two resistors are connected to the terminals of the same integrated circuit. 5 and 5, 6), wherein at least two other resistors (3, 7) are incorporated into said integrated circuit (9), the ends of which are connected to separate terminals of the same integrated circuit. 2. An integrated active filter according to claim 1, characterized in that one end of a series of three connected resistors (4, 5 and 6) is connected by the output of the first inverting amplifier (10) and the other end of said triple is coupled to the input of the next the inverting amplifier (12), wherein the node between the first double resistors (4, 5) is connected to the input of the remaining inverting amplifier (11) and joining the other pair of resistors (5, 6) is connected to the output the same inverting amplifier. , 5 drawings