DE10012519A1 - High pass circuit with gyrator has inductance implemented as gyrator with transistor with resistor between base and collector, series circuit capacitor and resistor between base and emitter - Google Patents

Abstract

The circuit has a capacitance, an inductance and a resistance, whereby the inductance is implemented as a gyrator (G) with a transistor (T) with a resistor (R6) between its base and collector connections and a series circuit with a capacitor (C4) and a resistor (R4) between its base and emitter connections. Independent claims are also included for the following: an amplifier circuit, a transmitter and a receiver.

Description

The invention relates to a high-pass circuit with a capacitance, an inductance and a resistance.

Such high-pass circuits are known in a wide variety of configurations and are needed in a variety of applications. As examples Receiver and transmitter devices for radio transmission, radio transmission or called phones or wireless microphones. Especially in low frequency assemblies, high-pass circuits are required.

In a simplest embodiment, a known high-pass circuit has a capacitor, which is connected in series to a parallel connection a coil and a resistor. The output signal of the high pass circuit is tapped at the center of this series connection. Advantageous in such  Circuits is that they are almost noiseless because of ideal coils and condensate generate no thermal noise themselves. However, the disadvantage is that Use of expensive and difficult to obtain coils.

The use of coils is avoided by the well-known high pass circuits in which operational amplifiers or transistor voltage followers in active filters. With such high-pass circuits, the Signal, however, pass through a noisy amplifier circuit. This makes the Noise voltage appearing at the output of the high-pass filter is much larger compared to the noise voltage at the output of a passive filter circuit. Even at frequencies far above the filter cut-off frequency, there is noise active filter at the output.

The invention is therefore based on the object of a high-pass circuit admit that is as low-noise as possible and without using coils is coming. In particular, the high-pass circuit in devices for audio Transmission, e.g. B. in wireless microphones.

This object is achieved by a high-pass circuit according to claim 1.

The invention is based on the idea of the coil at a known high to replace pass circuits by a gyrator circuit that only a few transi interfere, preferably has a single transistor. The coil could also can be replaced by an operational amplifier that is connected to capacitors is. However, this solution would also cause significant noise because the numerous semiconductors and resistors within the operational amplifiers Generate noise.

Advantageous configurations of the high-pass circuit, in particular the gyrator circuit, are specified in the subclaims.  

Especially in gyrator circuits with a single transistor, the noise can can be significantly reduced by strong negative feedback. The one in the Series connection between the base connection and the emitter connection of the Capacitance used by the transistor is converted into an inductance mirrored. Leave it through suitable wiring with different resistances So the DC and DC voltage operating point of the transistor to adjust. The one in the series connection between the base connection and emitter The final resistor is used for negative feedback and reduces noise and Non-linearity of the gyrator circuit.

To suppress hum and noise of the operating voltage are ins special designs with signal coupling at the center of the series circuit and with one at the base connection against a reference potential, in particular against ground, connected resistance advantageous.

To further reduce the distortion factor and intermodulation, the can be preferred used single transistor also by a Darlington circuit, for example with two transistors.

The impedance responses of the gyrator circuits used in the invention are are comparable to the impedance responses of coils that are relatively large series resistances and at the same time relatively small parallel resistances, d. H. low grades, exhibit. This leads, for example, to the realization of the inventions high pass circuit according to the invention with two capacitors and a gyrator circuit the frequency response of the frequency response of a high-pass filter second Order corresponds, although three orders (two capacitors and a gyra gate circuit) are available.

The invention also relates to an amplifier circuit, a transmitter and a receiver device that described a high-pass circuit according to the invention exhibit. The high-pass circuit according to the invention can preferably be used in circuits  for audio transmission, e.g. B. in wireless microphones. It can also be used in low-frequency modules that are said to be particularly low-noise use the high-pass circuit according to the invention advantageously.

The invention is explained in more detail below with reference to the drawings. Show it:

Fig. 1, 2-known high-pass circuits,

FIGS. 3 to 6 different embodiments of the gyrator circuit according to the invention,

Shows a gyrator circuit according to the invention tontransistor. 7 with a Darling,

Fig. 8 circuit an embodiment of a high-pass filter according to the invention,

Fig. 9 shows a frequency response of the high pass circuit shown in Fig. 8, and

Fig. 10 shows the course of the noise voltage density of a high-pass circuit according to Fig. 8.

Fig. 1 shows a known high-pass circuit including a capacitor C1 and a parallel circuit of a coil L1 and a resistor R1. This circuit filters out the frequencies below a cutoff frequency, which is determined by the dimensioning of the components, from an AC voltage supplied by an AC voltage source V1 at the input. The disadvantage of this high-pass circuit is that a large and relatively expensive coil must be used, which should often be avoided in practice.

A further known high-pass circuit is shown in FIG. 2, which has an operational amplifier O as the active element. The use of coils is avoided, however, such a high-pass circuit shows considerable noise due to the large number of semiconductors and resistors within the operational amplifier O.

A first embodiment of a gyrator circuit according to the invention for a high-pass circuit is shown in FIG. 3. A series circuit comprising a capacitor C4 and a resistor R4 is arranged in the negative feedback path from the base terminal B to the emitter terminal E of the transistor T. In addition, there is a resistor R5 between the base connection B and the center point M of this series circuit, which together with a further resistor R6 between the base connection B and the collector connection K of the transistor T serves to set the DC operating point of the transistor T. Another opponent was R7 between a supply voltage V2 and the collector terminal K, serves to determine the DC operating point of the transistor T. The output signal, ie the inductance L (jw), this gyrator circuit is tapped at the collector terminal K of the transistor T.

Resistor R4 is used for negative feedback and reduces noise and Non-linearity of the gyrator circuit. The capacitance C4 is in this circuit mirrored by the transistor T in an inductance L.

Another embodiment of a gyrator circuit according to the invention is shown in FIG. 4. In contrast to the embodiment shown in FIG. 3, the resistance R5 from the base connection B is applied to the ground potential serving as the reference potential. In addition, the resistor R7 is connected directly to the emitter terminal E of the transistor T to ground. In this circuit variant, the signal is coupled out at the center M of the series circuit located in the negative feedback path, which is advantageous with regard to the suppression of hum and noise in the operating voltage.

The signal decoupling in the embodiment shown in FIG. 5 also takes place at this center point M. However, the resistor R5 serving for setting the DC voltage operating point is connected directly between base connection B and emitter connection E of transistor T, and the resistor R7 lies from this center point M. against mass.

Compared to the exemplary embodiment shown in FIG. 5, the resistor R5 in the exemplary embodiment shown in FIG. 6 is again directly connected to ground from the base connection B, as a result of which the aforementioned suppression of hum and noise of the operating voltage can be achieved.

Fig. 7 shows an embodiment of a gyrator circuit in which, starting from the embodiment shown in Fig. 5, the transistor T is replaced by a Darlington circuit D which has two transistors T1 and T2, the base terminal B2 of the second transistor T2 with the collector terminal K1 of the first transistor T1 and the collector terminal K2 of the second transistor T2 are connected to the emitter terminal E1 of the first transistor T1. The emitter terminal E2 of the second transistor T2 is connected to a supply voltage V2. In addition, there is a resistor R8 between the emitter terminal E2 and the base terminal B2 of the transistor T2. By using this Darlington circuit, a further reduction in the harmonic distortion and the intermodulation can be achieved.

A high-pass circuit according to the invention with a gyrator circuit, as shown in FIG. 4, is shown in FIG. 8. This has a first capacitance C5, the gyrator circuit G to ground described in FIG. 4, a second capacitance C6 and again to ground a resistor R9, from which the output signal is tapped. The frequency response and the course of the noise voltage density of such a high-pass circuit in a practical implementation are shown in FIGS. 9 and 10. Although there are three orders in this high-pass circuit, namely the two capacitances C5 and C6 and the gyrator circuit G, the frequency response of this high-pass filter corresponds to the frequency response of a second-order high-pass filter.

With appropriate dimensioning of the components of the invention High pass circuit can be a low noise high pass filter with a cutoff frequency of 80 Hz to suppress wind noise. This filter can be used in a dynamic microphone for wireless audio transmission without using a microphone with a 200 ohm voice coil  Signal-to-noise ratio deteriorates. Such a voice coil rustles thermal with only 1.8 nV / √Hz. The frequency responses of such according to the invention High pass circuits are almost identical to the frequency response of an LC Second-order high-pass filter with a cut-off frequency of 80 Hz and a high pass hung at 180 Hz of approx. 0.5 dB. Depending on the specific implementation of the circuit Arrangements differ essentially in the suppression of Ripple of the operating voltage and the distortion factor.

The invention allows a high-pass filter with a noise voltage of 0.35 nV / √Hz (at 3 kHz) can be realized, which works almost noise-free. The maximum input voltage for 1% distortion factor is 3.4 Vpp operating tension. The dynamic range of such a high-pass filter is approx. 150 dB, which is an improvement of at least 20 dB known operational amplifier circuits is achieved.

The invention is not restricted to the embodiments shown. Terms Lich the specific design of the high-pass circuit, especially the Gyrator circuit, and in terms of dimensioning, there are numerous variants conceivable, which should be encompassed by the invention.

Claims (11)

1. high-pass circuit with a capacitance, an inductance and an opposing stand, characterized in that the inductance is realized by a gyrator circuit with a transistor. 2. High pass circuit according to claim 1, characterized in that between the collector connection and the base connection of the A transistor is arranged in a resistor and that between the base connection and Emitter connection of the transistor a series circuit of a capacitance and a resistance. 3. high pass circuit according to claim 2, characterized in that the collector connection of the transistor to a Supply voltage is connected and that the output signal of the gyrator circuit at the center of the series circuit between the capacitance and the Resistance can be tapped. 4. High pass circuit according to claim 3, characterized in that a resistor at the base terminal of the transistor is connected to a reference potential. 5. High pass circuit according to claim 3 or 4, characterized in that at the emitter terminal of the transistor or at Center of the series connection between the capacitance and the resistance Resistance to ground is connected. 6. high pass circuit according to claim 3, characterized in that between the base connection and emitter connection of the Transistor a resistor is connected.   7. high pass circuit according to claim 2, characterized in that a counter at the collector terminal of the transistor stood against a supply voltage potential that is connected between Basic connection and center point of the series connection between the capacitance and a resistor is connected to the resistor and that the output signal of the Gyrator circuit can be tapped at the collector connection. 8. High pass circuit according to one of the preceding claims, characterized in that the transistor by a Darlington circuit, in particular with two transistors. 9. amplifier circuit, in particular for a wireless microphone, with a high-pass circuit according to one of the preceding claims. 10. Transmitting device with a high pass circuit according to one of the previous claims. 11. Receiver device with a high pass circuit according to one of the previously outgoing claims.