US3191125A - Transmission line apparatus having a non-linear detector element and a direct-coupledline-terminating resistor in close electrical proximity - Google Patents

Transmission line apparatus having a non-linear detector element and a direct-coupledline-terminating resistor in close electrical proximity Download PDF

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US3191125A
US3191125A US176227A US17622762A US3191125A US 3191125 A US3191125 A US 3191125A US 176227 A US176227 A US 176227A US 17622762 A US17622762 A US 17622762A US 3191125 A US3191125 A US 3191125A
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transmission line
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James K Hunton
Russell B Riley
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HP Inc
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01PWAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
    • H01P1/00Auxiliary devices
    • H01P1/005Diode mounting means

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  • This invention relates to power detecting devices and more particularly to a crystal rectifier and mount therefor which provide substantially flat power detection and low voltage standing-wave ratio over a wide band of fre quencies.
  • Crystal detectors for monitoring power in coaxial transmission lines generally comprise commercially available crystal rectifiers and other circuit elements contained within a mounting fixture. These elements are disposed within the fixture to provide not only a detector output signal but also termination for the transmission line.
  • the power which is applied to the detector from a coaxial line is received within the fixture by the crystal rectifier and by a resistive device.
  • the output signal is provided by the crystal rectifier and the line termination is provided by the resistive device. Since the package which surrounds the crystal rectifier of a commercially available unit is fairly bulky, the resistive device is generally located a considerable distance from the crystal rectifier. Crystal detectors of this type are described in US. Patent 2,810,- 829 issued to N. B. Schrock on Oct. 22, 1957.
  • Crystal detectors of this type generally provide, over a wide band of frequencies, power detection signals having characteristic curves which are flat only to within three decibels and voltage standing-wave ratios of the order of 2.5 to 1. Variations in the output signal and in the standing-wave ratio are due primarily to the distance between the crystal rectifier and the resistive device, and are particularly large it this distance is around one-quarter wavelength of the applied signal. In addition, large reflections are produced by the crystal rectifier. Thus, the impedance of the rectifier as seen at the terminals of the resistive device may vary widely with changing frequency. This impedance may be quite low at frequencies for which the distance approaches one-quarter wavelength. It is necessary to insert an additional resistance in series with the crystal rectifier to maintain high impedance at these critical frequencies.
  • the impedance of the crystal rectifier as seen at the terminals of the resistive device can become very high.
  • the disadvantages generally inherent in the resulting design include poor line termination and the development of power detection signals having characteristic curves which are flat'only to within a few decibels substantially over the entire operating band.
  • the required terminating resistor and crystal rectifier are contained in a single unit.
  • the unit includes two sections which are adapted to be connected to the conductors of a transmission line and which are separated by an insulator.
  • a resistance film deposited about the insulator connects the two sections.
  • a capacitor to pass the high-frequency energy is provided by a third section disposed near one of the two sections.
  • a crystal rectifier is connected between the other of the two sections and the third section.
  • the unit is contained in a fixture or mount which includes a conventional type-N coaxial connector and an output connector.
  • a ring of lossy material is disposed about the unit to improve the standingwave ratio and flatten the characteristic curve of the detector output signal over the operating band of frequen- CIBS.
  • FIGURE 1 is a cross-sectional view of a coaxial power detector in accordance with the present invention.
  • FIGURE 2 is an enlarged cross-sectional view of the apparatus used in the detector of FIGURE 1.
  • FIG. 1 Referring now to the cross-sectional view of the detector in FIGURE 1, there is shown an envelope 9 attached to the outer ring 11 and the ground conductor 13 of the conventional type-N connector.
  • the high frequency signal under test is applied to the power detector through the ground connector 13 and connector pin 15 from a coaxial transmission line.
  • a short section of transmission line is provided by the inner surface 16 of envelope 9 and the conductive path including connector pin 15, inner conductor 17 and the first section 19 of apparatus 21.
  • the elements of this transmission line are held in coaxial alignment by insulator 23.
  • Apparatus 21 is connected to receive the signal appearing on this transmission line between the first section 19 and the second section 25.
  • a resistive film 49 deposited on the insulator 29 and connected between the two sections thus serves as a terminating resistor for the transmission line.
  • a third section 33 of apparatus 21 is attached to the second sect-ion 25 and is insulated therefrom by a layer of dielectric material 35. These two sections provide a capacitive path to ground for high frequency signals appearing on section 33.
  • a non-linear device such as a semi-conductor diode 47 or variable reactor is disposed within the insulator 29 and is connected between the first and third sections of the apparatus.
  • a ring of lossy material 31 is disposed about the first section 19 and is held in place by the ground ring 27.
  • An outer cap 37 is attached to envelope 9 and contains BEST AVAILABLE COPY resistor and the non-linear detector element is reduced substantially to zero in the present invention.
  • the critical relationship which exists in conventional power detectors between the spacial separation of elements and the wavelength of an applied signal at a particular frequency is thus eliminated.
  • Substantially constant line termination and hence, low voltage standing-wave ratio over a broadband of frequencies is obtained.
  • the flatness of the detector output signal is improved by the ring 31 of lossy material about the conductive path of the transmission line. This material may be of a type which is responsive to the magnetic fields about the conductive path and increases the power loss in the transmission line as the frequency of the applied signal increases.
  • this material has the effect of introducing resistance in the transmission line in series with the nonlinear detector element. This effect further improves the voltage standing-wave ratio and flattens the frequency response characteristic of the detector.
  • the impedance of the power detector decreases with increasing frequency. This causes the voltage standing-wave ratio to increase. Placing the ring 31 of lossy material around the conductive path has the elfect of inserting resistance in series with the power detector. This effective series resistance adds to the impedance of the power detector. The combination of the effective series resistance and the impedance of the power detector terminates a coaxial line with a lower voltage standing-wave ratio than is possible without the aid of the lossy material.
  • the apparatus 21 of FIGURE 1 is shown in crosssectional view in FIGURE 2.
  • the first section 19 includes a wafer post 45 to which is attached a wafer 47 of semiconductor material.
  • the first sect-ion 19 is bonded to one end of the cylindrical insulator 29 and the second section 25 is bonded to the opposite end of the insulator 29.
  • a film of resistive material 49 is deposited on the surfaces of insulator 29 in contact with the first section 19 to the second section 25.
  • the high frequency signal is applied to the apparatus between the first and second sections, as shown in FIGURE 1.
  • the second section 25 is connected at ground potential.
  • a signal thus appearing on the first section 19 is terminated by the resistive film 49 which has a resistance that is substantially equal to the characteristic impedance of the transmission line to which the apparatus is connected.
  • the signal appearing on the first section 19 is rectified by the non-linear element including wafer 47 and appears on the third section 33 as the detector output signal.
  • the second and third sections of the apparatus constitute a by-pass capacitor for shunting any high frequency signal appearing on the third section 33 to ground.
  • the apparatus of the present invention thus reduces the spacial separation between the line terminating resistor and the crystal rectifying unit substantially to zero.
  • the advantage of combining these elements in a single unit is that the operating characteristics of the present apparatus are substantially free from the variations in response with changing frequency inherent in conventional power detectors.
  • the apparatus and mount therefor of the present invention provide extremely flat frequency response and low voltage standing-wave ratios over a broadband of operating frequencies.
  • the power detector of the present invention combines desirable operating characteristics with ease and simplicity of manufacture.
  • High frequency signal apparatus comprising a first section and a second section axially separated from said first section by an insulator, an output section disposed near said second section and insulated therefrom, a nonlinear circuit clement within said insulator and connecting said output section and the first section, and resistance means on said insulator and connecting the first and second sections.
  • High frequency signal apparatus comprising a first section and a second section axially separated from said first section by an insulator, an output section, a rectifying element connecting said output section and the first section, resistance means disposed about said insulator and connecting said first and second section-s, and capacitance means connecting the output section and said second section.
  • High frequency signal apparatus comprising first and second sections separated by an insulator, an output terminal, a non-linear circuit element connecting the output terminal and said first section, the apparatus being adapted to receive a high frequency signal between the first and second sections, and resistance means on said insulator connecting said first and second sections.
  • High frequency signal apparatus comprising first and second sections disposed coaxially at opposite ends of a cylindrical insulator, the apparatus being adapted to receive a high frequency signal between the first and second sections, a third section disposed near said second section and separated therefrom by a dielectric, an unidirectional conduction element within the insulator and connecting the first and third sections, a resistive film deposited about said insulator and connecting the first and second sections, and means connected to said second and third sections for deriving an output from said device.
  • a signalling device comprising an envelope and means forming a conductive path within said envelope, apparatus Within said envelope and including first and second conductive sections disposed at opposite ends of a cylindrical insulator, said first section being connected to said means forming said conductive path and said second section being connected to said envelope, resistance means disposed about said insulator and connecting said first and second sections, a third conductive section disposed near said second section and separated therefrom by a dielectric, a non-linear device within said insulator and connecting said first and third sections, a ring of lossy material disposed coaxially about said insulator, the material being responsive to the electromagnetic field about said conductive path and introducing power loss that increases with frequency, and means connected to said envelope and said third section and forming an output circuit for said device.
  • a signalling device comprising an envelope and means forming a conductive path therewithin, apparatus within said envelope including first and second conductive sections separated by an insulator, said first section being connected to said means forming said conductive path and said second section being connected to said envelope, resistance means disposed about said insulator and connecting said first and second sections, a third conductive section disposed about said second section and separated therefrom by a dielectric, a non-linear element within said insulator and connecting said first and third sections, and means connected to said third section and to said envelope and forming an output circuit for said device.

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V I 7' E l W 333 24s XR Light; 2088 REFEREiCE M BEST AVA\LABLE COPY June 22, 1965 .K. HUNTON ETAL 3,191,125
TRANSMISSION LINE APPARATUS HAVING A NON-LINEAR DETECTOR ELEMENT AND A DIRECT-COUPLED LINE-TERMINATING RESISTOR IN CLOSE ELECTRICAL PROXIMITY Filed Feb. 28, 1962 INVENTORS JAMES K. HUNTON RUSSELL B. RILEY ATTORNEY United States Patent 3 191,125 TRANSMISSION LINE APPARATUS HAVING A NON-LINEAR DETECTOR ELEMENT AND A DIRECT-COUPLED LINE-TERMINATING RESIS- TOR IN CLOSE ELECTRICAL PROXIMITY James K. Hunton, Los Altos, and Russell B. Riley, Palo Alto, Calif., assignors to Hewlett-Packard Company, Palo Alto, Calif., 21 corporafion of California Filed Feb. 28, 1962, Ser. No. 176,227 6 Claims. (Cl. 329-162) This invention relates to power detecting devices and more particularly to a crystal rectifier and mount therefor which provide substantially flat power detection and low voltage standing-wave ratio over a wide band of fre quencies.
Crystal detectors for monitoring power in coaxial transmission lines generally comprise commercially available crystal rectifiers and other circuit elements contained within a mounting fixture. These elements are disposed within the fixture to provide not only a detector output signal but also termination for the transmission line. The power which is applied to the detector from a coaxial line is received within the fixture by the crystal rectifier and by a resistive device. The output signal is provided by the crystal rectifier and the line termination is provided by the resistive device. Since the package which surrounds the crystal rectifier of a commercially available unit is fairly bulky, the resistive device is generally located a considerable distance from the crystal rectifier. Crystal detectors of this type are described in US. Patent 2,810,- 829 issued to N. B. Schrock on Oct. 22, 1957.
Crystal detectors of this type generally provide, over a wide band of frequencies, power detection signals having characteristic curves which are flat only to within three decibels and voltage standing-wave ratios of the order of 2.5 to 1. Variations in the output signal and in the standing-wave ratio are due primarily to the distance between the crystal rectifier and the resistive device, and are particularly large it this distance is around one-quarter wavelength of the applied signal. In addition, large reflections are produced by the crystal rectifier. Thus, the impedance of the rectifier as seen at the terminals of the resistive device may vary widely with changing frequency. This impedance may be quite low at frequencies for which the distance approaches one-quarter wavelength. It is necessary to insert an additional resistance in series with the crystal rectifier to maintain high impedance at these critical frequencies. At other frequencies the impedance of the crystal rectifier as seen at the terminals of the resistive device can become very high. Thus the design of a broadband crystal detector which properly terminates the transmission line over a wide range of frequencies involves a compromise between these two extreme conditions. The disadvantages generally inherent in the resulting design include poor line termination and the development of power detection signals having characteristic curves which are flat'only to within a few decibels substantially over the entire operating band. Thus, in applications requiring power detection signals having characteristic curves which are flat to within 0.5 decibel or less and requiring low voltage standingwave ratios over a broadband of frequencies, it is desirable to eliminate the effects of the distance between the crystal rectifier and the resistive device. In addition, it is desirable to provide a simple mounting fixture for these elements which can be readily manufactured.
Accordingly, it is an object of the present invention to provide an improved power detector.
It is another object of the present invention to provide a crystal rectifier which can be used in a simple mounting aesr AVAILABLE COPY ice fixture to terminate a transmission line and to provide a power detection signal.
It is still another object of the present invent-ion to provide a power detector in which the crystal rectifier and terminating resistance are combined in a single unit.
In accordance with the illustrated embodiment of the present invention the required terminating resistor and crystal rectifier are contained in a single unit. The unit includes two sections which are adapted to be connected to the conductors of a transmission line and which are separated by an insulator. A resistance film deposited about the insulator connects the two sections. A capacitor to pass the high-frequency energy is provided by a third section disposed near one of the two sections. A crystal rectifier is connected between the other of the two sections and the third section. The unit is contained in a fixture or mount which includes a conventional type-N coaxial connector and an output connector. A ring of lossy material is disposed about the unit to improve the standingwave ratio and flatten the characteristic curve of the detector output signal over the operating band of frequen- CIBS.
These and further objects of the present invention will be apparent from a reading of this specification when taken in connection with the accompanying drawing in which:
FIGURE 1 is a cross-sectional view of a coaxial power detector in accordance with the present invention, and
FIGURE 2 is an enlarged cross-sectional view of the apparatus used in the detector of FIGURE 1.
Referring now to the cross-sectional view of the detector in FIGURE 1, there is shown an envelope 9 attached to the outer ring 11 and the ground conductor 13 of the conventional type-N connector. The high frequency signal under test is applied to the power detector through the ground connector 13 and connector pin 15 from a coaxial transmission line. A short section of transmission line is provided by the inner surface 16 of envelope 9 and the conductive path including connector pin 15, inner conductor 17 and the first section 19 of apparatus 21. The elements of this transmission line are held in coaxial alignment by insulator 23. Apparatus 21 is connected to receive the signal appearing on this transmission line between the first section 19 and the second section 25. These two sections of the apparatus 21 are coaxially aligned and are bonded to the opposite ends of the cylindrical insulator 29. A resistive film 49 deposited on the insulator 29 and connected between the two sections thus serves as a terminating resistor for the transmission line. A third section 33 of apparatus 21 is attached to the second sect-ion 25 and is insulated therefrom by a layer of dielectric material 35. These two sections provide a capacitive path to ground for high frequency signals appearing on section 33. A non-linear device such as a semi-conductor diode 47 or variable reactor is disposed within the insulator 29 and is connected between the first and third sections of the apparatus. A ring of lossy material 31 is disposed about the first section 19 and is held in place by the ground ring 27.
An outer cap 37 is attached to envelope 9 and contains BEST AVAILABLE COPY resistor and the non-linear detector element is reduced substantially to zero in the present invention. The critical relationship which exists in conventional power detectors between the spacial separation of elements and the wavelength of an applied signal at a particular frequency is thus eliminated. Substantially constant line termination and hence, low voltage standing-wave ratio over a broadband of frequencies is obtained. In addition, the flatness of the detector output signal is improved by the ring 31 of lossy material about the conductive path of the transmission line. This material may be of a type which is responsive to the magnetic fields about the conductive path and increases the power loss in the transmission line as the frequency of the applied signal increases. It is believed that this material has the effect of introducing resistance in the transmission line in series with the nonlinear detector element. This effect further improves the voltage standing-wave ratio and flattens the frequency response characteristic of the detector. In one embodiment of the present invention the impedance of the power detector decreases with increasing frequency. This causes the voltage standing-wave ratio to increase. Placing the ring 31 of lossy material around the conductive path has the elfect of inserting resistance in series with the power detector. This effective series resistance adds to the impedance of the power detector. The combination of the effective series resistance and the impedance of the power detector terminates a coaxial line with a lower voltage standing-wave ratio than is possible without the aid of the lossy material.
The apparatus 21 of FIGURE 1 is shown in crosssectional view in FIGURE 2. The first section 19 includes a wafer post 45 to which is attached a wafer 47 of semiconductor material. The first sect-ion 19 is bonded to one end of the cylindrical insulator 29 and the second section 25 is bonded to the opposite end of the insulator 29. A film of resistive material 49 is deposited on the surfaces of insulator 29 in contact with the first section 19 to the second section 25. The third section 33, which includes whisker post =51, is attached to the second section 25 by a layer 35 of dielectric bonding material. The high frequency signal is applied to the apparatus between the first and second sections, as shown in FIGURE 1. The second section 25 is connected at ground potential. A signal thus appearing on the first section 19 is terminated by the resistive film 49 which has a resistance that is substantially equal to the characteristic impedance of the transmission line to which the apparatus is connected. In addition, the signal appearing on the first section 19 is rectified by the non-linear element including wafer 47 and appears on the third section 33 as the detector output signal. The second and third sections of the apparatus constitute a by-pass capacitor for shunting any high frequency signal appearing on the third section 33 to ground.
The apparatus of the present invention thus reduces the spacial separation between the line terminating resistor and the crystal rectifying unit substantially to zero. The advantage of combining these elements in a single unit is that the operating characteristics of the present apparatus are substantially free from the variations in response with changing frequency inherent in conventional power detectors. In addition, the apparatus and mount therefor of the present invention provide extremely flat frequency response and low voltage standing-wave ratios over a broadband of operating frequencies. Further, the power detector of the present invention combines desirable operating characteristics with ease and simplicity of manufacture.
We claim:
1. High frequency signal apparatus comprising a first section and a second section axially separated from said first section by an insulator, an output section disposed near said second section and insulated therefrom, a nonlinear circuit clement within said insulator and connecting said output section and the first section, and resistance means on said insulator and connecting the first and second sections.
2. High frequency signal apparatus comprising a first section and a second section axially separated from said first section by an insulator, an output section, a rectifying element connecting said output section and the first section, resistance means disposed about said insulator and connecting said first and second section-s, and capacitance means connecting the output section and said second section.
3. High frequency signal apparatus comprising first and second sections separated by an insulator, an output terminal, a non-linear circuit element connecting the output terminal and said first section, the apparatus being adapted to receive a high frequency signal between the first and second sections, and resistance means on said insulator connecting said first and second sections.
4. High frequency signal apparatus comprising first and second sections disposed coaxially at opposite ends of a cylindrical insulator, the apparatus being adapted to receive a high frequency signal between the first and second sections, a third section disposed near said second section and separated therefrom by a dielectric, an unidirectional conduction element within the insulator and connecting the first and third sections, a resistive film deposited about said insulator and connecting the first and second sections, and means connected to said second and third sections for deriving an output from said device. I 5. A signalling device comprising an envelope and means forming a conductive path within said envelope, apparatus Within said envelope and including first and second conductive sections disposed at opposite ends of a cylindrical insulator, said first section being connected to said means forming said conductive path and said second section being connected to said envelope, resistance means disposed about said insulator and connecting said first and second sections, a third conductive section disposed near said second section and separated therefrom by a dielectric, a non-linear device within said insulator and connecting said first and third sections, a ring of lossy material disposed coaxially about said insulator, the material being responsive to the electromagnetic field about said conductive path and introducing power loss that increases with frequency, and means connected to said envelope and said third section and forming an output circuit for said device.
6. A signalling device comprising an envelope and means forming a conductive path therewithin, apparatus within said envelope including first and second conductive sections separated by an insulator, said first section being connected to said means forming said conductive path and said second section being connected to said envelope, resistance means disposed about said insulator and connecting said first and second sections, a third conductive section disposed about said second section and separated therefrom by a dielectric, a non-linear element within said insulator and connecting said first and third sections, and means connected to said third section and to said envelope and forming an output circuit for said device.
References Cited by the Examiner UNITED STATES PATENTS 2,510,613 6/50 Weber et a1. 333-81 2,557,122 6/51 Leiphart 3 29-162 2,636,120 4/53 Bird et al. 329l62 X 2,810,829 10/57 Schrock 329-162 ROY LAKE, Primary Examiner.

Claims (1)

  1. 3. HIGH FREQUENCY SIGNAL APPARAUS COMPRISING FIRST AND SECOND SECTIONS SEPARATED BY AN INSULATOR, AN OUTPUT TERMINAL, A NON-LINEAR CIRCUIT ELEMENT CONNECTING THE OUTPUT TERMINAL AND SAID FIRST SECTION, THE APPARATUS BEING ADAPTED TO RECEIVE A HIGH FREQUENCY SIGNAL BETWEEN THE FIRST AND SECOND SECTIONS, AND RESISTANCE MEANS ON SAID INSULATOR CONNECTING SAID FIRST AND SECOND SECTIONS.
US176227A 1962-02-28 1962-02-28 Transmission line apparatus having a non-linear detector element and a direct-coupledline-terminating resistor in close electrical proximity Expired - Lifetime US3191125A (en)

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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3422364A (en) * 1964-05-15 1969-01-14 Int Standard Electric Corp Pulse amplitude modulation to pulse width modulation converter
US3452279A (en) * 1966-03-03 1969-06-24 Bell Telephone Labor Inc Test fixture for measuring impedance parameters of diodes operated at microwave frequencies
US3541480A (en) * 1968-09-30 1970-11-17 Sage Laboratories Butt diode contacting
US4238732A (en) * 1979-03-29 1980-12-09 General Dynamics Corporation Method of qualifying diodes for a microwave power combiner

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2510613A (en) * 1945-03-30 1950-06-06 Polytechnic Inst Brooklyn Variable attenuator
US2557122A (en) * 1951-06-19 Coaxial crystal detector and line
US2636120A (en) * 1949-06-16 1953-04-21 Bird Electronic Corp Combined voltage divider and crystal cartridge assembly for highfrequency electricaldevices
US2810829A (en) * 1954-09-27 1957-10-22 Hewlett Packard Co Broad band coaxial crystal detector and line termination device

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2557122A (en) * 1951-06-19 Coaxial crystal detector and line
US2510613A (en) * 1945-03-30 1950-06-06 Polytechnic Inst Brooklyn Variable attenuator
US2636120A (en) * 1949-06-16 1953-04-21 Bird Electronic Corp Combined voltage divider and crystal cartridge assembly for highfrequency electricaldevices
US2810829A (en) * 1954-09-27 1957-10-22 Hewlett Packard Co Broad band coaxial crystal detector and line termination device

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3422364A (en) * 1964-05-15 1969-01-14 Int Standard Electric Corp Pulse amplitude modulation to pulse width modulation converter
US3452279A (en) * 1966-03-03 1969-06-24 Bell Telephone Labor Inc Test fixture for measuring impedance parameters of diodes operated at microwave frequencies
US3541480A (en) * 1968-09-30 1970-11-17 Sage Laboratories Butt diode contacting
US4238732A (en) * 1979-03-29 1980-12-09 General Dynamics Corporation Method of qualifying diodes for a microwave power combiner

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