Systems and methods for impedance synthesis

Electricity: measuring and testing – Impedance – admittance or other quantities representative of...

Reexamination Certificate

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C379S377000, C379S398000

Reexamination Certificate

active

06573729

ABSTRACT:

BACKGROUND OF THE INVENTION
1. The Field of the Invention
The present invention relates to impedance synthesis. More specifically, the present invention relates to the synthesis of user specified source or load impedances using digital processing.
2. The Prior State of the Art
Ordinarily, circuits are designed such that the load impedance is much greater than the impedance of the source that is driving the load. Otherwise, the load impedance may have an adverse effect on the source voltage by causing the output voltage of the source to drop. This undesirable result is related to the finite value of the source impedance. Transmission lines, however, are an exception to this general rule. In the case of transmission lines, it is desirable that the load impedance match the impedance of the transmission line for several reasons.
In a basic form, a transmission line is two or more parallel conductors which connect a source to a load. The load presents an impedance to the transmission line and the transmission line presents a characteristic impedance, which is usually a combination of the source impedance and the impedance of the transmission line, to the load. When the transmission line is attached to a load having an impedance equal to the characteristic impedance of the transmission line, the power in the signal transferred to the load is maximized and the signal is not reflected back to the source. These benefits are important for many different applications. If the power transfer is not maximized, it is possible that the connecting device will be unable to properly interpret the signal. If signal reflections are present on the transmission line, then the signal becomes difficult to demodulate and additional circuitry is required to remove the reflections or echoes.
One common example of a transmission line which is used for moderate frequencies is a parallel conductor, which is frequently used in telephone networks. The parallel conductors of a telephone network are often referred to as the tip and ring. Thus, the tip and ring comprise the transmission line and the load impedance may be embodied as a telephone, modem or other device capable of connecting to the telephone network.
The telephone network specifies the characteristic impedance of the transmission line which must be matched by a connecting device in order to fully transfer power and avoid signal reflection. However, the impedance specified by the telephone network is usually only an approximation of the actual impedance, which results from such variables as: the variations in the length of the transmission lines to the connecting device from the central office; various wiring topologies within an intermediary installation such as a series of parallel transmission lines within a business or other structure; and intrinsic variations in the transmission lines themselves. The actual characteristic impedance presented by the telephone network is difficult to precisely match and is usually only approximated.
With regard to telephone networks, the problem is complicated by the fact that telephone networks across the world specify different characteristic impedances. In this situation, it is feasible that a device functioning perfectly in one telephone network will encounter difficulty in another telephone network. Because telephones, modems and other telephonic devices are being used world wide, it is necessary to enable a telephonic device to function in any telephone network environment. While many devices are capable of operating in different networks, the result is not always satisfactory. One solution is to characterize the impedances of the various telephone networks into groups and physically place more than one impedance in the device. The appropriate impedance is then selected using appropriate switching technologies such as relays or field effect transistor (FET) switches. This method has several disadvantages. First, control circuitry must be employed to control the relays and switches, which is not a trivial task because of the high voltages which may be present on many transmission lines. Because of the high voltages, the components used for the switches and relays can be large and expensive and must be rated to withstand the high voltages which can be present on a transmission line.
While placing multiple impedances on a device to permit a device to function in more network, the physical impedances physically placed on the device are designed to approximate, rather than match, the characteristic impedances that may be encountered in different telephone networks, which results in less than optimal power being transferred to the load as well as signal reflections back to the signal source. Also, many devices, such as modems, have limited printed circuit board surface area on which to place these additional circuit elements and a relatively large number of discrete circuit components such as resistors, operational amplifiers and capacitors can require significant surface area. Further, the combined tolerances of the passive and active circuit components may result in a large variance from the desired impedance.
The problem of properly terminating a transmission line has also been addressed in terms of impedance synthesis. However, these attempts have involved the use of discrete circuit components such as resistors and operational amplifiers. These methods, however, are limited to synthesizing real or resistive impedances. Recursive digital filters have also been utilized, but this approach introduces incidental shunting impedances, whose effects must be eliminated. In addition, digital filters are capable of introducing unacceptable delays.
OBJECTS AND BRIEF SUMMARY OF THE INVENTION
In view of the foregoing and other problems in the prior art, it is therefore an object of one embodiment of the present invention to provide a system and method that can synthesize an impedance.
Another object of one embodiment of the present invention is to provide a system and method that accomplishes impedance synthesis by substantially matching a load impedance.
Yet another object of one embodiment of the present invention to synthesize a specified source impedance.
It is yet another object of one embodiment of the present invention to synthesize negative impedances.
It is a further object of one embodiment of the present invention to gyrate inductive and capacitive circuit elements.
It is another object of one embodiment of the present invention to synthesize prescribed impedance across a pair of terminals.
In summary, these and other objectives are obtained with embodiments of the present invention that provide systems and methods for synthesizing a prescribed impedance either across a pair of terminals or at a source. In general, generating or sinking a current synthesizes the impedance, such that the ratio of the voltage to the current is the prescribed impedance. The synthesis of impedance has particular application in at least two general instances: load impedance synthesis and source impedance synthesis. Impedance synthesis is not, however, limited to these examples, but can be adapted to many different circumstances. Because the signal is attenuated, it does not interfere with the operation of the network connected device. Embodiments also provide the ability to synthesize desired termination impedance, so that the network connected device matches the characteristic impedance of the network.
Load impedance synthesis usually occurs in the context of a transmission line. The transmission line exhibits an associated characteristic impedance that should be matched by the load in order for the power transfer to be maximized and in order to avoid signal reflection back to the source. To synthesize the known load impedance, the voltage across the transmission line terminals is measured. This measured voltage is then converted to its digital equivalent. A digital processor processes the digital equivalent according to a scaling factor related to the prescribed impedance. The output of the digital processor controls a current s

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