US2410076A

US2410076A - Negative impedance circuit

Info

Publication number: US2410076A
Application number: US478113A
Authority: US
Inventors: Kenneth S Johnson
Original assignee: Bell Telephone Laboratories Inc
Current assignee: AT&T Corp
Priority date: 1943-03-05
Filing date: 1943-03-05
Publication date: 1946-10-29
Anticipated expiration: 1963-10-29

Description

1946- K. s. JOHNSON NEGATIVE IMPEDANCE CIRCUIT Filed March 5, 1943 AAAAAAAAAAAAAAA AAAAAAAAAAA "II I" IIYIIVIYVV'VYVVV VVY riAr AlAAlAAAllA ""1""! //v VENTOR K S. JOHNSON ATTORNEY Patented Oct. 29, 1946 2,410,076 NEGATIVE IMPEDANCE CIRCUIT Kenneth S. Johnson, South Orange, N. 1., aa-

signor to Bell York Telephone Laboratories, Incorporated. New York, N. Y.,

a corporation New Application March 5, 1943, Serial No. 478,113

8 Claims. (Cl. 178-44) The present invention relates to circuits using negative impedance and more especially to the provision of auxiliary impedance, which may comprise a network'of impedances, tor modifying the characteristic of the negative impedance.

One known type of negative impedance device consists or a substance having a negative temperature coeilicient of resistance connected in circuit with a source or biasing current which raises the temperature of the substance to such a point that its resistance changes in response to small impressed current fluctuations in such manner that the terminal voltage across the substance decreases as the current through the device increases. In other words, the device operates on a falling portion of its volt-ampere characteristic. This type of negative impedance device has been termed thermistor because its resistance changes as a function of its temperature. This and other types of devices that exhibit a characteristic with a region in which the slope is downward are referred to as negative resistance devices since the derivative of voltage with respect to current variation is negative in sign.

It has been shown that the time lag of heating inherent in a thermistor is equivalent to an inductance in the equivalent electrical network. For some purposes this time lag is undesirable and what is desired is a negative resistance with substantially no reactance.

It is an object of the present invention to compensate or neutralize to a material degree the reactive component oi impedance of a negative resistance device such as a thermistor.

A further object of the invention is to provide a negative resistance whose magnitude varies with frequency. Thermistors that are suitable for carrying out the objects of this invention may comprise any of a number of known substances including particularly semiconductors, such as silver sulphide, boron, oxides of uranium or other substances having negative temperature coeflicients of resistance. Such thermistors have been constructed having a frequency response range covering the range of commercial speech and even extending to many kilocycles per second. One type of thermistor construction capable of re sponding to frequencies of this order 01. band width is disclosed in United States patent to G. L. Pearson 2,276,864, granted March 17, 1942,

The nature and objects of the present invention will appear more fully from the following detailed description together with the accompanying drawing in which:

Figs. 1 to 4, inclusive, are impedance network diagrams to illustrate how the equivalent circuit of a thermistor may be combined with a compensating network according to the invention;

Fig. 5 shows one method of coupling a thermistor to a line according to the invention;

Fig. 6 shows a circuit for utilizing a thermistor in accordance with the invention; and

Fig. 7 shows curves to be referred to in the de- .scription.

cuit by the inductance L. As the frequency in- I creases, the negative resistance effect eventually disappears and the thermistor behaves as an ohmic resistance R. In terms of the thermistor this occurs when the frequency exceeds the highest frequency which the temperature variations can follow. In terms of the equivalent circuit, this occurs at the frequency at which the impedance of the inductance L becomes so great that substantially no current can traverse the path through -r and all of the current must take the path through R.

In accordancewith the invention, this time lag of the thermistor is reduced or substantially neutralized by connecting in shunt across the thermistor terminals a circuit comprising a positive resistance of numerical value nearly equal to r in series with a capacity C of proper size, as indicated in Figs. 2 and 3. It can be shown that the impedance Z of the circuit of Fig. 2 (which is identical to the circuit of Fig. 3 but uses a different notation) is r(r+Ar) or, using the notation of Fig. 3,

.(r+ Ar):c+ry

which, since it contains no reactance term, represents a pure resistance whose magnitude varies with frequency. Moreover, the resistance can be positive or negative depending upon the frequency. This effect is illustrated by the graphs in F18. 7.

Curve '1 is the measured curve of a boron thercharacteristic.

mistor without the compensating shunt circuit of the invention. Its resistance is negative at all of the frequencies plotted but the value is decreasing with increasing frequency so that at some frequency in the neighborhood of '7 kilocycles its resistance will turn positive. Solid line curve A is in two parts (A1, A1) and represents the ideal case in which A1 is zero and, therefore, 1' is numerically exactly equal to r. This curve passes from minus infinity to plus infinity in go-' ing through a frequency of about 5 kilocycles. This curve represents an unstable case and cannot be actually realized in practice but can be approached. Dotted curve B is a curve calculated for the case where Ar has a small positive value large enough to give stable operation. This curve is interesting in exhibiting increasing negative resistance eifect with rising frequency over a considerable range below 4 kilocycles and a steeply rising characteristic between 4 and 5 kilocycles, this steep portion being entirely in the negative resistance range for several hundred cycles. This offers the possibility of a circuit with net gain and with its gain varying rapidly as a function of frequency. The computations for these curves assumed values as follows:

R=600 ohms L=0.00577 henry C=0.096 microfarad r=-240 ohms The curve A was computed for r=240 ohms and curve B was computed for r=250 ohms.

In the case of curve B since the neutralization of the inductive reactance L is incomplete, the impedance Z is not a pure resistance but has a phase angle varying with frequency. The real or resistance component is plotted in curve B.

The invention provides what is believed to be a highly novel circuit combination or unit capable of general application. This unit is illustrated in Fig. 4 as comprising a thermistor l having a battery II and variable resistance I! for applying an adjustable bias to the thermistor to bias it to the desired point along its negative resistance The current may be passed through the thermistor -by a conductive path or applied to a heating winding surrounding the thermistor. Choke coil i3 is for preventing current variations representing signals or other waves to be amplified from being shunted through the bias current circuit. The compensating or neutralizing circuit already described comprises a resistance l4 and capacity it proportioned in magnitude with relation to the negative resistance and positive inductance eflects inherent in the thermistor operation as already set forth.

Fig. 5 shows a circuit for introducing into a line or circuit represented by the fragment of line II a resistance or a gain varying with frequency over a definite range. The thermistor is coupled to the line I8 through transformer I! inserted between the thermistor and a bridge across line l6, including condenser II which may be a stopping condenser or a tuning condenser for tuning the shunt branch. The transformer i! may serve to step the impedance up or down as between the line and the thermistor circuit. The resistance I may be partly or wholly a resistance having a highly positive temperature coefllcient of resistance to insure stability if high local circulatory currents should tend to 6 shows a circuit for using the compensated themistor of the invention for converting frequency variations into amplitude variations. A source of variable frequency is shown at II which may in practice comprise a vacuum tube oscillator with a movable condenser plate for varying the frequency. The output of source II is sent over a circuit or line 2| to the point at which the variations in frequency are to be indicated. Resistance 22 (which could be replaced by transformer I l and condenser ll of Fig. 0, if desired) is for coupling the line H to the indicator circuit comprising thermistor units II to I8 (Fig. 4) and a suitable current responsive element shown for illustration as a moving coil instrument 23 having a pen 24 movable across a paper 2! fed along by rollers 2| to make a record of the frequency variations.

The frequency of source may be varied by hand to transmit signs or signals or may be varied by a meter, fioat, steering wheel or any other movable member whose position or movement is to be indicated at a distance. The resulting changes in frequency are translated by the thermistor circuit into amplitude variations which are rectified by any suitable type rectifier 21 shown as a solid element rectifier, such as copper oxide. The rectifier current flows through the colic! the instrument 23 and the alternating current, component flows through shunting condenser 28. If operation is desired in accordance with curve B of Fig. 7, the source 20 may have a mean frequency slightly above 4 kilocycles (e. g. 4,200 cycles) and the maximum range of variation may be between 4,000 cycles and 4,400 cycles. Over this entire range the resistance is negative and varying at a steep rate so that the thermistor acts as an amplifier and at the same time as a very eil'ective conversion circuit for changing frequency modulated waves to amplitude modulated waves. By using two channels like the one in Fla. 6 and suitably coordinating them, a telautograph system may be provided. Other applications of the invention will occur to persons skilled in the art, from the illustrative examples that have been given showing the 45 principle of operation.

The invention is not to be construed as limited to the specific forms that have been disclosed but the scope is defined in the claims, which follow.

50 What is claimed is:

1. A circuit comprising a thermistor and a bias current supply circuit for causing said thermistor to develop an impedance effect having a negative resistance component and an inductive compo- 55 nent, and a circuit connected in shunt relation to said thermistor and comprising positive resistance and capacitive reactance proportioned to substantially neutralize the inductive reactance of said thermistor impedance.

- 2. A circuit comprising a thermistor and a bias current supply circuit for causing said thermistor to develop an impedance effect having a negative resistance component and a reactive component, and a circuit connected in shunt relation to said thermistor and comprising positive resistance and a reactive impedance proportioned to substantially neutralize the reactive component of said thermistor impedance.

3. In combination a thermistor, means to bits said thermistor to the negative resistance region of its volt-ampere characteristic whereby said thermistor exhibits negative resistance over a given frequency range with an inductive reactance, and a passive network connected in shunt across said thermistor of such character- 5. A frequency-amplitude conversion circuit comprising a negative resistance device having inherent reactance and a compensating network having resistance and reactance shunted across said negative resistance device for giving a resultant impedance approaching a pure resistance whose magnitude varies with frequency.

6. A circuit for converting frequency variations to amplitude variations comprising a thermistor of sumciently high response speed to permit its temperature to follow said frequency variations, said thermistor exhibiting an inductive reactive effect, and means to reduce said inductive eflect comprising a compensating network in shunt relation to said thermistor comprising positive resistance and capacitance.

7. In combination with a circuit carrying currents of diflerent frequency, a circuit unequally responsive to currents of difierent frequencies comprising a thermistor shunted by resistance and capacitance of such value as to give a resultant impedance approaching a pure resistance whose magnitude varies markedly at said different frequencies.

8. A circuit comprising a pair of terminals and two parallel branches connected between said terminals, the first branch comprising a negative resistance device which is electrically equivalent in impedance to a pure resistance connected between said terminals, shunted by a negative resistance of value --1' and an inductance L in series with each other, and the second branch consisting of a resistance r+Ar in series with a capacitance C of magnitude given by