351 F2d 1008 Application of William J Popowsky

351 F.2d 1008

Application of William J. POPOWSKY.

Patent Appeal No. 7442.

United States Court of Customs and Patent Appeals.

November 10, 1965.

Arthur H. Swanson, Lockwood D. Burton, Philadelphia, Pa., for appellant.

Clarence W. Moore, Washington, D. C. (Jere W. Sears, Washington, D. C., of counsel), for the Commissioner of Patents.

Before WORLEY, Chief Judge, and RICH, SMITH, and ALMOND, Judges.

SMITH, Judge.

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Appellant appeals from a decision of the Board of Appeals affirming the examiner's rejection of claims 13 and 14 of appellant's application, serial No. 841,763 filed September 23, 1959 entitled "Measuring Apparatus."


The issue for determination is whether appellant's device is obvious in view of the prior art under 35 USC § 103.1 The references remaining2 in support of the rejection are as follows:


Geffcken et al., (British) 235,526 June 17, 1926


Jenkins, Voltage-Sensitive Capacitors, Electrical Manufacturing, Dec. 1954, pp. 83-88, 300, 302.

The Invention

As stated by appellant:


The claims under appeal * * * are drawn to an electrical signal transducer for use in industrial process control applications. The transducer is characterized in that it receives a unidirectional analog voltage signal and, through its unique circuitry, produces a corresponding unidirectional analog current signal which may be economically transmitted and utilized at a distant point with little or no tendency for deterioration in the transmitted signal. * * * [Emphasis by appellant.]


The parties agree that the circuit diagram which comprises Fig. 3 of the drawings of the appealed application best explains the claimed invention.


NOTE: OPINION CONTAINING TABLE OR OTHER DATA THAT IS NOT VIEWABLE Appealed claim 13 reads on the circuit shown in Fig. 3 of the application in the following manner, as set forth in the solicitor's brief:3

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Claim 13. An electrical                     Figure 3
signal transducer operative
in response to

an electrical unidirectional-voltage        Signal (e in) at terminals
input signal                                55 and 56

to produce a corresponding                  Signal across load 39
unidirectional current output

said transducer comprising an               Transistor 12

a positive feedback circuit                 Tank circuit 17, 50 connected
* * *,                                      in Hartley manner between
                                            collector 15 (via 20) and base
                                            13 (via 18)

a sensing network forming                   Tank 17, 50
part of said positive feedback
circuit and including a
variable attenuation means
* * *,

said variable attenuation                   Barium titanate capacitor
means comprising two serially-connected     51-53 connected in series
unidirectional-voltage                      with barium titanate capacitor
sensitive reactance                         53-52
elements * * *,

an input circuit * * *                      Input terminals 55 and 56 are
                                            connected to variable capacitor
                                            50 directly and through
                                            choke coils 57, 58.

and an output circuit * * *                 Choke 35, resistance 36, battery
                                            10, load 39, resistor 30,
                                            diode 31, etc.

The board relies in its decision upon certain teachings found in Jenkins, in connection with the circuit diagram shown in Fig. 17 of that article:




The Jenkins article as it relates to the circuit of Fig. 17 states:


* * * Voltage-sensitive capacitors have been used * * * in circuits for frequency and phase modulation. These systems employ a voltage-sensitive capacitor as one element of an oscillator tank circuit so that variations in capacitance caused by the modulating signal produce corresponding variations of ascillator frequency. Fig. 17 shows a frequency-modulated oscillator using two voltage-sensitive capacitors, C1 and C2, as modulating elements. They are connected in series with respect to the r-f potential and in parallel with respect to the modulating potential. A bias battery is used to set the voltage value between the capacitors. Frequency deviations of ± 2 percent in the 50 to 500 mc range have been reported * * *. Under extreme conditions the amplitude modulation is appreciable, but is negligible for smaller deviations.


Comparing the subject matter of claim 13 to Jenkins, the board agreed with the examiner that there was no essential difference in structure except for the output circuit in claim 13 and that it would be obvious to insert a meter as disclosed in Geffcken in the plate circuit of the Jenkins circuitry to satisfy this limitation. The position of the examiner thus affirmed by the board is that it is well known that the variation of the frequency of an oscillator also produces current changes and that the use of the particular capacitors claimed in an oscillator is old as shown by the references.


The Geffcken reference relates specifically to the detection of magnetic bodies. It comments that previous devices acted on the basis of a variation in the effective capacity of a "field-producing condenser" or the self-induction of a "field producing coil," stating that:


For rendering such variation of the alternating current magnitudes noticeable devices sensitive to frequency were hitherto used and connected to an oscillation generator. In order to obtain sufficient sensitiveness for the purpose above referred to, complicated circuit arrangements must be provided.

The reference further comments:


The present invention obviates complicated alternating current arrangements. It converts variations of the alternating current magnitudes directly to direct current fluctuations as it uses variations in the electrode current of a suitably constructed valve generator as a measurement for the variations of its condition of oscillation.


It is already known that in valve generators a variation in the electrode current can occur simultaneously with variations in the generator oscillation. This phenomenon has been used in a scientific measurement for determining the variation of capacities. * * * A vacuum tube oscillator circuit used in Geffcken is shown in Fig. 1 of that reference:




It is contemplated that the tuned circuit 4 react in response to the presence of a magnetic body to modify the oscillating or tank circuit 2 of the oscillator to cause a variation in anode current which can be observed in a galvanometer 6.


Concerning Fig. 1, Geffcken states, in pertinent part, as follows:


The anode current of the valve generator is observed by means of the galvanometer 6 which is bridged by a condenser 7. The galvanometer may also be replaced by a compensating circuit or the like. * * *


The arrangement shown in Figure 1 corresponds with an intermediate circuit generator. The circuit 4 exerts its greatest action on the generator 1, 2, 5 in the neighbourhood of the resonance position. The action is noticed therein that besides the variations of the amplitudes of the generator oscillation the phase angle of the generator is changed. At the same time the phase of the grid potential is changed as this is induced by the generator current. There is thus positively effected a variation of the anode current which may be observed by the galvanometer 6. * * *


It seems to us that Geffcken, taken as a whole, fairly discloses that variations of the tuning of the tank circuit of an oscillator, including the capacitance in such circuit, can produce variations in the current in the plate circuit. It further discloses that the variations in such current may be shown on a measuring instrument and utilized as an indicator. The Jenkins reference, similarly taken as a whole, teaches that voltage-sensitive capacitors in an oscillator tank circuit will react to a signal input to produce corresponding variations in oscillatory frequency.


Appellant argues that the references do not teach a control device incorporating the following relationships: (1) a unidirectional-voltage input signal which produces variations in the capacitance of the voltage-sensitive capacitors; (2) which, in turn, produce corresponding variations of the magnitudes of oscillations in the tank circuit; (3) which, in turn, produce corresponding variations in the current in the plate circuit of the oscillator; (4) which, in turn, represent a unidirectional-current output signal for control purposes.


Despite appellant's arguments, consideration of the disclosures of Jenkins and Geffcken convince us that they constitute a clear teaching that variations in capacitance of voltage-sensitive capacitors connected in the tank circuit of an oscillator may be utilized to produce corresponding variations in current in the plate circuit of the oscillator.4 It is true that the references do not disclose that such arrangement may be used as a means for operating on a unidirectional-voltage signal. However, we think it would have been obvious to a person of ordinary skill in the art that a variable unidirectional-voltage signal might be applied to the terminals of the voltage-sensitive capacitors for the purpose of attaining a corresponding output current signal in accordance with the broad language of the claims. The subject matter in issue thus must be held to be unpatentable under the provisions of 35 U.S.C. § 103.


The decision of the board is affirmed.




MARTIN, J., took no part in the consideration or decision of this case.



Appellant argues that the board affirmed a ground of rejection which was never formally made by the examiner. We do not agree. Appellant argues further and we agree that the examiner's rejection is based on obviousness under 35 U.S.C. § 103. This rejection was affirmed by the board and has been argued by the parties in this court. Accordingly, our decision may be confined to the issue of obviousness


The board disagreed with the examiner's reasoning that the appealed claims were unpatentable over claim 1 of "A" in view of the disclosures of "B" and Jenkins. It agreed with the examiner that it would be obvious to utilize a feature found in Geffcken with the disclosure of Jenkins. An examination of the board's reasoning does not show it to be improper or inconsistent. Appellant's arguments to the contrary are not convincing


The other appealed claim, claim 14, is dependent on claim 13 and specifies that the voltage-sensitive elements are capacitors (shown in Fig. 3 at 50) the capacitance of which is variable in response to voltage signals applied across them. The parties agree and we concur that the claims stand or fall together


Appellant, while maintaining that his device produces a unidirectional-current output "whichmay be economically transmitted and utilized at a distant point," states in his specification that the output terminals may be "arranged to have a suitable indicator and/or controller connected thereto * * *. It will be readily apparent that the apparatus may be used in any indicating or controlling function in the manner well known in the art."

The claims, as shown below, do not require an indicator, controller, or load. The claimed transducer utilizes the existence of a unidirectional-current signal in the plate circuit, measurable at the designated output terminals. We find this to be fully met by Geffcken.


An electrical signal transducer operative in response to an electrical unidirectional-voltage input signal to produce a corresponding unidirectional current output signal; said transducer comprising an amplifier, a positive feedback circuit connected around said amplifier to produce therein electrical oscillations having an adjustable amplitude, a sensing network forming a part of said positive feedback circuit and including a variable attenuation means to control the amplitude of said oscillations in accordance with the magnitude of the unidirectional-voltage input signal, said variable attenuation means comprising two serially-connected unidirectional-voltage sensitive reactance elements each having a connection in common and having separate end terminals, an input circuit for applying the unidirectional-voltage input signal to said sensing network, said input circuit including a first and a second input terminal, a connection from said first terminal to the common connection of said serially-connected elements and a connection from said second terminal to the end terminals of said elements, and an output circuit for said transducer responsive to the amplitude of said oscillations to produce an output current signal in said output circuit of said transducer corresponding to the magnitude of the unidirectional-voltage input signal


The invention as set forth in Claim 13 wherein said voltage sensitive elements are capacitors the capacitance of which are variable in response to voltage signals applied thereacross