Balancing impedance circuit
First Claim
1. A hybrid balancing impedance for a telephone cable pair characterized bya low frequency noninductive resistive-capacitive networkk effective to provide an impedance function inversely proportional to the square root of frequency at low frequencies, anda high frequency nonreactive resistive network effective to provide a constant impedance function at high frequencies.
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Abstract
A class of electronic hybrids is disclosed in which the line balancing impedance is made frequency-sensitive in order to better match the frequency characteristic of the connected line and is made voltage-controlled in order that a single network can be used to match a variety of different gauges of telephone cable pairs. The matching impedances are synthesized utilizing RC networks and the voltage control is realized with two-node Miller effect impedance multiplication circuits realized by long-tailed pairs for synthesizing hyperbolic tangent impedance functions under the control of a voltage.
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Citations
9 Claims
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1. A hybrid balancing impedance for a telephone cable pair characterized by
a low frequency noninductive resistive-capacitive networkk effective to provide an impedance function inversely proportional to the square root of frequency at low frequencies, and a high frequency nonreactive resistive network effective to provide a constant impedance function at high frequencies. - View Dependent Claims (2, 3, 4, 5)
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3. The balancing impedance according to claim 2 characterized in that
said functions of wire gauge are realized with two-node Miller effect multipliers connected to said low and high frequency impedances. -
4. The balancing impedance according to claim 3 characterized in that
said multipliers each comprise a long-tailed pair having one multiplier related to the gauge of said telephone cable pairs. -
5. The balancing impedance according to claim 1 characterized in that
said low frequency network comprises a capacitance, a resistance and a plurality of serially connected resistance-capacitance legs, all connected in parallel.
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6. An impedance synthesis circuit comprising
a first and a second impedance connected in series and each providing a different frequency characteristic in a different frequency range, a first multiplier connected to one end of said first impedance, a second multiplier connected to the midpoint of said first and second impedances, means for summing the outputs of said first and second multipliers and applying the sum to the remaining end of said second impedance, and linearly related multiplier control signals connected to said multipliers.
Specification