Wave-shaping Patents (Class 333/20)
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Patent number: 6326861Abstract: A method for generating a closely spaced train of extremely high voltage short pulses. The method involves generating the train of pulses by combining a plurality of harmonic amplitudes to construct said pulses, via a Fourier construction. Any arbitrary pulse shape can be reproduced simply by changing the amplitude of the harmonics. The train of high voltage electrical pulses produced by the method of the present invention is particularly well suited for the acceleration of particles by applying the pulses to an appropriate accelerating structure.Type: GrantFiled: September 21, 1999Date of Patent: December 4, 2001Assignee: FELtech CorporationInventor: Francesco Villa
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Patent number: 6320475Abstract: The present invention relates to a printed circuit board of the present invention comprising: a main transmission line; and additional transmission lines positioned on both sides of the main transmission line and parallel-connected to the main transmission line by way of selectors.Type: GrantFiled: August 11, 1999Date of Patent: November 20, 2001Assignee: NEC CorporationInventor: Hiroshi Kamiya
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Patent number: 6320480Abstract: A programmable phase shifter (20, 40, 54, 60, 62) includes a variable delay line formed from a nonlinear transmission line (NLTL) (26, 28, 46, 28), which enables the device to be used in applications where the frequency of the input signal varies. A variable DC bias applied to the NLTL (26, 28, 46, 48) varies the NLTL's phase velocity and delay. Since the characteristic impedance of a transmission line changes as a function of the DC bias, the input voltage standing wave ratio (VSWR) also changes. In order to compensate for the change in the input VSWR, a pair of NLTLs (26, 28, 46, 48) are coupled at the input and output to a pair of hybrid couplers (22, 42). In an alternate embodiment of the invention, the hybrid couplers (22, 24) are replaced with 180° power splitters (42, 44) in order to reduce distortion of the device. In other embodiments of the invention (40, 54), a nonlinear transmission lines are used to form both discretely variable and continuously variable digital phase shifters (60, 62).Type: GrantFiled: October 26, 1999Date of Patent: November 20, 2001Assignee: TRW Inc.Inventors: Mark Kintis, Daniel K. Ko, Stephen A. Maas
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Publication number: 20010011930Abstract: A nonlinear transmission-line waveform generator for generating a comb of frequencies and relatively short duration pulses, for example, in the range of picoseconds and tens of picoseconds, that are adapted to being utilized with ultra wideband radios in order to improve the bandwidth of such radios by an order of magnitude, for example, up to tens and even hundreds of GHz. In particular, the nonlinear transmission line waveform generator in accordance with the present invention consists of a microstrip or coplanar waveguide line. In accordance with an important aspect of the invention, the &Dgr;C/&Dgr;V characteristic of the nonlinear transmission line is matched to the frequency and amplitude of the input sinusoid. By matching the &Dgr;C/&Dgr;V characteristics of the nonlinear transmission line to the input sinusoid, the output of the nonlinear transmission line produces a comb of frequencies that are multiples of the input sinusoid frequency, making it suitable as a harmonic generator.Type: ApplicationFiled: February 5, 1999Publication date: August 9, 2001Inventors: MARK KINTIS, DANIEL K. KO, FLAVIA S. FONG, STEPHEN A. MAAS
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Patent number: 6169585Abstract: In a circuit arrangement for demodulating an intermediate-frequency video signal generated while using a Nyquist edge, having a phase-locked loop (1) including a phase detector (3), a loop filter (4) and a voltage-controlled oscillator (5), and a video demodulator (2), the intermediate-frequency video signal being applied to the phase detector (3) and the output signal of the phase-locked loop (1) being applied to the video demodulator (2), which converts the intermediate-frequency video signal into a baseband video signal, phase fluctuations contained in the carrier of the intermediate-frequency video signal due to its generation while using a Nyquist edge are compensated in that the phase comparator (3) operates, by approximation, independently of modulation in the control range of the intermediate-frequency video signal, in that the baseband video signal is present in an inverted form with respect to the intermediate-frequency video signal, and in that a correction signal is derived from the baseband videoType: GrantFiled: February 23, 1999Date of Patent: January 2, 2001Assignee: U.S. Philips CorporationInventor: Thomas Hafemeister
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Patent number: 6057569Abstract: The present invention provides a diode limiter device in which a first penetration hole is formed on a wall surface of an H surface; the PIN diode is supported by the PIN diode mounting side of the post with the PIN diode being electrically connected to the waveguide at the first penetration hole; a second penetration hole is formed on the other wall surface opposite to the wall surface; a second conductive boss which grasps the PIN diode with the post is electrically insulated and supported with respect to the second penetration hole; a wiring substrate with the detection diode and the resistor mounted thereon is installed; and the wiring substrate is supported in the second penetration hole by a third boss, thereby improving productivity and reducing cost.Type: GrantFiled: June 17, 1998Date of Patent: May 2, 2000Assignee: New Japan Radio Co., Ltd.Inventors: Ikuo Kisanuki, Manabu Tomita
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Patent number: 6014409Abstract: A network interface for receiving both high speed signals and low speed signals includes a passive filter manufactured entirely from passive electronic elements. The filter filters the low speed signal when a low speed signal is received, and does not distort a high speed signal transmitted to an encoder/decoder device when a high speed signal is received.Type: GrantFiled: February 5, 1997Date of Patent: January 11, 2000Assignee: Cabletron Systems, Inc.Inventor: Robert Curtis
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Patent number: 5900681Abstract: A device for generation of electric square pulses with a short rise time, comprises at least an energy-storing capacitor in the form of a coaxial cable with an insulated screen, wherein essentially the whole coaxial cable is wound up in an inner closed cylindrical container of metal, a direct-voltage source for charging this screen, and devices for short-circuiting the screen to zero potential during generation of pulses. These devices together with the inner cylindrical metal container are enclosed in an outer closed container of metal, and one end of the coaxial cable is intended for connection to a load and the other end of the coaxial cable terminates with a resistor which has the characteristic impedance of the cable. Between the inner cylindrical container and the outer container, a ferrite ring-core is placed around the devices for short-circuiting and both cable ends.Type: GrantFiled: December 12, 1997Date of Patent: May 4, 1999Assignee: ABB Research Ltd.Inventors: Kenneth Johansson, Christer Tornkvist
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Patent number: 5815537Abstract: A wireless digital communication device having a pulse shaping network for pulse shaping digital signals before modulation. The pulse shaping network comprises a shift register to which data to be modulated are fed. Outputs of the shift register are connected to control inputs of switched weighted current sources. The switched weighted current sources are summed over an output resistor. An adjustment voltage for adjusting the magnitude of the shaped data is fed to one input of a differential amplifier, a reference resistor being coupled to another input of the amplifier, and to a reference current source which is mirrored into the switched weighted current sources. Thus, an accurate and easily adjustable pulse shaping network is obtained.Type: GrantFiled: July 18, 1996Date of Patent: September 29, 1998Assignee: U.S. Philips CorporationInventor: Daniel J. G. Janssen
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Patent number: 5804977Abstract: An RF matching network provides matching between a charged first transmission line and a relay circuit which is switched to connect the charged transmission line to one end of a second transmission line to generate a high-voltage, high-current test pulse for a DUT connected to the other end of the second transmission line. A low pass filter section of the RF matching network suppresses transient and ringing signals which might pass through the parasitic capacitance of the relay circuit and which trigger the prematurely trigger the DUT. To remove residual charge after discharging the first transmission line, the transmission line is grounded with a GND relay before leakage tests are conducted to prevent electrically stress of destruction of leakage testing circuitry if the residual charge is not dissipated before testing for leakage.Type: GrantFiled: April 23, 1997Date of Patent: September 8, 1998Inventor: Rosario J. Consiglio
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Patent number: 5798579Abstract: A high voltage generator including a Marx Generator (1) provides an output of up to 200 kV at a pulse repetition rate of up to 1 kHz. Discharge is triggered by over-volting a first stage (2a) of the Marx Generator, each stage including a hydrogen spark gap switch (5). By inhibiting the charging power supply (7) for a short time after each discharge, recovery of the dielectric is ensured, enabling high repetition rates without the need for gas flow.Type: GrantFiled: June 13, 1996Date of Patent: August 25, 1998Assignee: Matra BAe Dynamics (UK) Ltd.Inventor: Andrew J. McPhee
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Patent number: 5796314Abstract: A high-power RF switching device employs a semiconductor wafer positioned in the third port of a three-port RF device. A controllable source of directed energy, such as a suitable laser or electron beam, is aimed at the semiconductor material. When the source is turned on, the energy incident on the wafer induces an electron-hole plasma layer on the wafer, changing the wafer's dielectric constant, turning the third port into a termination for incident RF signals, and. causing all incident RF signals to be reflected from the surface of the wafer. The propagation constant of RF signals through port 3, therefore, can be changed by controlling the beam. By making the RF coupling to the third port as small as necessary, one can reduce the peak electric field on the unexcited silicon surface for any level of input power from port 1, thereby reducing risk of damaging the wafer by RF with high peak power.Type: GrantFiled: May 1, 1997Date of Patent: August 18, 1998Assignee: Stanford UniversityInventors: Sami G. Tantawi, Ronald D. Ruth, Max Zolotorev
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Patent number: 5789994Abstract: A differential nonlinear transmission line (NLTL) circuit has anti-parallel diode pairs along a balanced transmission line to generate well defined high-speed pulses with sharp positive and negative transitions from a time varying input signal. The input signal may carry an arbitrary DC bias voltage component that is suitable for digital logic circuits, such as current mode logic (CML) employing differential inputs.Type: GrantFiled: February 7, 1997Date of Patent: August 4, 1998Assignee: Hughes Electronics CorporationInventors: Michael G. Case, Gopal Raghavan
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Patent number: 5684341Abstract: An electromagnetic generator for working electrically conducting objects with current and magnetic field pulses having a high rate of rise as expressed by dI/dt and dB/dt includes primary windings of a pulse transformer that are arranged in pairs so that their primary currents generate a single current pulse on the secondary side of the pulse transformer. The pulse transformer has as secondary coil comprised of a longitudinally slit pipe on which the insulated primary windings are placed. Contact blocks are attached as current outputs next to the longitudinal slit and in the middle of pipe for the connection of an external low-ohmic peak-current loop which encloses a magnetic field concentrator that is made in one or several parts and that can accept one or several metal work pieces.Type: GrantFiled: July 29, 1994Date of Patent: November 4, 1997Assignee: Magnet-Physik Dr. Steingroever GmbHInventor: Erich Steingroever
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Patent number: 5675275Abstract: In order to sample high-frequency signals, it is necessary to have a needle pulse train and a needle pulse train which is inverted with respect thereto. By means of a switch (T) which is controlled by a clock signal (U), a positive operating voltage (U.sub.B+) is applied for a limited period of time to a first conductor (L.sub.1) and a negative operating voltage (U.sub.B-) is applied for a limited period of time to a second conductor (L.sub.2). The two conductors (L.sub.1, L.sub.2) are connected via a respective diode (D.sub.1, D.sub.2), which are biased differently, to a respective resistor (RV.sub.1, RV.sub.2), which is connected to ground, and to a respective capacitor (C.sub.1, C.sub.2). The respective capacitors connected to a respective further resistors (RL.sub.1, RL.sub.2), which is connected to ground, the needle pulse train being present at one resistor and the needle pulse train which is inverted with respect to the first being present at the other resistor.Type: GrantFiled: May 7, 1996Date of Patent: October 7, 1997Assignee: Siemens AktiengesellschaftInventors: Patric Heide, Rudolf Schwarte
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Patent number: 5656873Abstract: A device for charging PFLs (Pulse Forming Lines) on a time scale of a few nanoseconds. The device includes a source transmission line (STL) connected through a switch to a pulse forming transmission line. The source line is initially charged while the PFL is uncharged, and the switch is open. The impedance of the STL is larger than the impedance of the PFL. The impedance of the STL is also tapered in order to effect an energy transfer efficiency approaching 100% from the STL to the PFL. In operation when the switch is closed, energy flows from the source line to the PFL. As the energy and voltage build on the PFL, an output switch closes and delivers the energy of the PFL to the output transmission line section. The impedance of the output transmission line section is matched to the PFL impedance so that all of the energy in the PFL flows into the output section in the form of a pulse.Type: GrantFiled: February 7, 1996Date of Patent: August 12, 1997Assignee: The United States of America as represented by the Secretary of the Air ForceInventors: James P. O'Loughlin, Diana L. Loree
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Patent number: 5651029Abstract: A waveform shaping circuit includes an input terminal, an output terminal, and a plurality of cascaded circuit stages. Each of the cascaded circuit stages includes a delay circuit having an output and an input, a current source, and a switch circuit, connected electrically to the output of the delay circuit and controlled by the delay circuit, for connecting electrically the current source to the output terminal. The input of the delay circuit of a first one of the circuit stages is connected electrically to the input terminal. The input of the delay circuit of remaining ones of the circuit stages is connected electrically to the output of the delay circuit of an immediately preceding one of the circuit stages. The delay circuits have equal delay times. The total delay time provided by the delay circuits of the circuit stages is equal to or is a multiple of half a bit time of the fundamental data rate.Type: GrantFiled: May 16, 1995Date of Patent: July 22, 1997Assignee: Myson Technology, Inc.Inventors: Tsen-Shun Yang, Chun-Ming Chou, Wen-Jung Su
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Patent number: 5650670Abstract: Complex and multi-cycle microwave pulse waveforms are generated by the transient discharge of an induction charged transmission line using only one fast switch. An essential feature of the transmission line circuit is the distinction between the ground planes of the bias circuit and the microwave circuit. This distinction permits spatial variation of the charge induced on the transmission line over sections of ground plane biased at different potentials. Rapid discharge of the biased ground plane sections produces a complex or multiple cycle voltage wave on the transmission line which results in multicycle microwave pulse generation. The transient discharge is initiated by a fast switch located in the microwave ground plane. The similarity between some operating characteristics of the herein described device and the traditional Frozen Wave Generator (FWG) justify naming the new device and Induction Charged Frozen Wave Generator (ICFWG).Type: GrantFiled: July 27, 1995Date of Patent: July 22, 1997Assignee: The United States of America as represented by the Secretary of the Air ForceInventor: James Bruce Thaxter
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Patent number: 5621255Abstract: A Marx generator, includes a number of capacitors (E) connected in series via spark gaps (E), between two output terminals and a power supply circuit that charges the capacitors in parallel. The capacitors are connected in series by a flat line formed of two metal strips running parallel and facing one another. These strips are connected together electrically at one end of the line and respectively to the output terminals at the other end and consist of one continuous strip and a second strip subdivided by transverse slots into successive plane sections interconnected in series alternately by a capacitor and a surface spark gap. A structure of this kind reduces the inductance of the generator and hence improves the rise time of the output pulses.Type: GrantFiled: March 15, 1994Date of Patent: April 15, 1997Assignee: Etat Francais represente par le Delegue General pour l'ArmementInventors: Jean-Francois Leon, Bernard Etlicher, Philippe Auvray, Henri Lamain
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Patent number: 5530298Abstract: A solid-state pulse generator for use in determining the output of a gas volume meter. A sensor detects a change in a magnetic field with rotation of a gas meter element and generates an electrical output pulse. A MOSFET switch having output terminals is coupled to the sensor for forming a closed circuit between the output terminals when the pulse is generated by the sensor thereby enabling a data collection circuit coupled to the MOSFET output terminals.Type: GrantFiled: September 3, 1993Date of Patent: June 25, 1996Assignee: Dresser Industries, Inc.Inventor: Richard R. Gerhold
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Patent number: 5519327Abstract: A pulse discharge circuit for pulse testing an integrated-circuit device under test (DUT) is provided which uses three separate switching relays S1, S2, and S3, which are operated in a predetermined sequence. For charging the capacitance of a pulse-forming transmission line, the relay contact of S1 is closed while the relay contacts of relays S2, S3 are both open. For discharging the charge on the transmission line to form a test pulse, the relay contact of S1 is first opened, and the relay contact of S2 is then closed while the relay contact of S3 is open. After each test pulse is generated and applied to a DUT, the condition of the DUT is determined by a leakage current measurement. The relay contact S2 is opened to isolate the pulse generator circuit and then the relay contact S3 is closed.Type: GrantFiled: June 10, 1994Date of Patent: May 21, 1996Assignee: VLSI Technology, Inc.Inventor: Rosario J. Consiglio
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Patent number: 5514918Abstract: A pulse generator is composed of switch means to switch supply of a first current through a circuit, a first condenser connected to the switch means in series and primary charged by the first current, voltage raising means having a primary winding serially connected to the first condenser and a secondary winding to obtain voltage output by the first current, magnetic switch means of current flow switchable having a primary winding serially connected to the secondary winding of the voltage raising means and a secondary winding, a second condenser connected to the secondary winding of the magnetic switch means and charged by the output therefrom, and discharging means connected to the second condenser to generate pulse discharge when charged voltage of the second condenser is applied thereto by switching the magnetic switch means.Type: GrantFiled: October 8, 1993Date of Patent: May 7, 1996Assignee: Kabushiki Kaisha MeidenshaInventors: Hiroshi Inatomi, Takashi Sakugawa, Hisashi Yanase, Takehisa Koganezawa, Kiyoshi Hara
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Patent number: 5422607Abstract: A phase linear filter for soliton suppression is in the form of a laddered series of stages of non-commensurate low pass filters with each low pass filter having a series coupled inductance (L) and a reverse biased, voltage dependent varactor diode, to ground which acts as a variable capacitance (C). L and C values are set to levels which correspond to a linear or conventional phase linear filter. Inductance is mapped directly from that of an equivalent nonlinear transmission line and capacitance is mapped from the linear case using a large signal equivalent of a nonlinear transmission line.Type: GrantFiled: February 9, 1994Date of Patent: June 6, 1995Assignee: The Regents of the University of CaliforniaInventor: Thomas E. McEwan
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Patent number: 5396198Abstract: A power source wiring supplies power to individual electronic circuits constituting an electronic circuit device. Load circuits are connected to the power source wiring within the range of an arrival time of a voltage noise occurring in the power source wiring in a time of about a half of a pulse width of a noise current at the time of the operation of the electronic circuit. Each of these load circuits includes a series circuit of a resistance and a capacitance.Type: GrantFiled: September 9, 1993Date of Patent: March 7, 1995Assignee: Hitachi, Ltd.Inventors: Hiroki Yamashita, Hiroyuki Itoh, Keiichirou Nakanishi, Tatsuya Saitoh, Tohru Kobayashi, Satoru Isomura
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Patent number: 5376903Abstract: In a pulse compression device, the pulses to be compressed being frequency modulated, the device comprises at least one transmission line, the cut-off frequency of which varies along its axis of propagation and means for the separation of an incident wave and a reflected wave, loaded by the transmission line and receiving the pulses to be compressed which get reflected along the transmission line, the variation of the cut-off frequency and the frequency modulation of the pulses being matched with each other. Application: high power pulse compression in microwave transmission. FIG. 3a.Type: GrantFiled: May 21, 1993Date of Patent: December 27, 1994Assignee: Thomson-CSFInventor: Gerard Kantorowicz
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Patent number: 5352627Abstract: A process for fabricating sequential inductors and varactor diodes of a monolithic, high voltage, nonlinear, transmission line in GaAs is disclosed. An epitaxially grown laminate is produced by applying a low doped active n-type GaAs layer to an n-plus type GaAs substrate. A heavily doped p-type GaAs layer is applied to the active n-type layer and a heavily doped n-type GaAs layer is applied to the p-type layer. Ohmic contacts are applied to the heavily doped n-type layer where diodes are desired. Multiple layers are then either etched away or Oxygen ion implanted to isolate individual varactor diodes. An insulator is applied between the diodes and a conductive/inductive layer is thereafter applied on top of the insulator layer to complete the process.Type: GrantFiled: May 10, 1993Date of Patent: October 4, 1994Inventor: Gregory A. Cooper
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Patent number: 5319665Abstract: A high power electromagnetic pulse driver for generating sub-microsecond rise time pulses having energy contents greater than 1 joule includes an electromagnetic pulse compressor and an electromagnetic shock line for compressing the leading edges of those pulses. The shock line may use non-linear materials whose permeability or permittivity vary greatly with varying field strength. One material whose permeability varies by a useful amount is metglass, an amorphous alloy of silicon and iron. The high power electromagnetic pulse driver may drive gas discharge lasers.Type: GrantFiled: November 6, 1992Date of Patent: June 7, 1994Assignee: Science Research LaboratoryInventor: Daniel L. Birx
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Patent number: 5291156Abstract: A method and apparatus for imparting a positive phase slope (i.e., a negative group delay) to a narrowband signals is disclosed which adjusts the phases of the various frequency components of a signal in a manner opposite to that of a delay line. The invention also permits the amount of phase slope to be adjusted, electronically, without the need for electro-mechanical apparatus or the interchange of cables. Furthermore, embodiments of the present invention are advantageous in that at the center of the operating band they maintain the phase of the delayed signal. These results are obtained in an illustrative embodiment of the present invention which divides the signal to be delayed into two signals which traverse different signal paths and are recombined in a signal combiner. The first signal path advantageously comprises a gain control block. The second signal path advantageously comprises a second gain control block and a fixed line delay which is not found in the first signal path.Type: GrantFiled: February 10, 1993Date of Patent: March 1, 1994Assignee: AT&T Bell LaboratoriesInventor: Bernard J. Arntz
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Patent number: 5274271Abstract: An inexpensive pulse generating circuit is disclosed that generates ultra-short, 200 picosecond, and high voltage 100 kW, pulses suitable for wideband radar and other wideband applications. The circuit implements a nonlinear transmission line with series inductors and variable capacitors coupled to ground made from reverse biased diodes to sharpen and increase the amplitude of a high-voltage power MOSFET driver input pulse until it causes non-destructive transit time breakdown in a final avalanche shockwave diode, which increases and sharpens the pulse even more.Type: GrantFiled: July 12, 1991Date of Patent: December 28, 1993Assignee: Regents of the University of CaliforniaInventor: Thomas E. McEwan
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Patent number: 5267020Abstract: A high bandwidth RF sampler using equivalent time sampling comprising an RF coplanar waveguide integrated with sampling diodes on a gallium arsenide substrate. A monolithic, integrated nonlinear transmission line is integrated on the same substrate to receive sample pulses. These pulses are reshaped by the nonlinear transmission line to have a very fast edge. This edge is differentiated by a shunt inductance of a short circuit termination of a slot line portion of the RF signal coplanar waveguide. The resulting delta function sample pulses cause the sample diodes and integrated capacitors to develop an intermediate output frequency which is a replica of the RF signal at a lower frequency and no voltage conversion loss. RF signals of up to 300 Ghz can be sampled using this circuit.Type: GrantFiled: October 17, 1988Date of Patent: November 30, 1993Assignee: Stanford UniversityInventors: Robert A. Marsland, Mark Rodwell, David M. Bloom
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Patent number: 5264800Abstract: A Monolithic Microwave Integrated Circuit (MMIC) for capturing transients in the GHz range is disclosed. The device includes a transmission line formed in a GaAs substrate. The transmission line includes a number of threshold devices forming shunts on the transmission line. The threshold devices are positioned at predetermined locations with respect to one another. A reference signal and an unknown signal are counter-propagated along the transmission line. When the two signals collide, they produce a collision voltage which exceeds the threshold voltage of the threshold devices. The voltage information is distributed along the predetermined length of several threshold devices. Thus, amplitude, phase, and timing information regarding the two signals may be obtained. This information may be utilized for triggering, clock interpolation, data demodulation, and other applications.Type: GrantFiled: September 15, 1992Date of Patent: November 23, 1993Assignee: The Board of Trustees of the Leland Stanford, Jr. Univ.Inventor: Alistair D. Black
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Patent number: 5256996Abstract: An integrated coplanar strip nonlinear transmission line comprising a substrate of gallium arsenide upon which a heavily doped buried layer and a lightly doped surface layer of epitaxially grown gallium arsenide are grown. Two parallel conductors are integThis work was funded by the United States Government's Office of Naval Research under contract No. N99914-85-K-0381. The United States Government has a paid up license in this technology.Type: GrantFiled: July 6, 1992Date of Patent: October 26, 1993Assignee: The Board of Trustees of the Leland Stanford, Junior UniversityInventors: Robert A. Marsland, Mark J. W. Rodwell, David M. Bloom
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Patent number: 5214318Abstract: A semiconductor integrated circuit device has, in one embodiment, a pair of signal transmission lines formed over and insulated from a semiconductor substrate, a first circuit formed in the semiconductor substrate and electrically connected with one end of the pair of signal transmission lines for sending an electric signal, and a second circuit formed in the semiconductor substrate and electrically connected with the other end of the pair of signal transmission lines for receiving the electric signal propagating over the transmission line pair. A control resistance is electrically connected between the pair of transmission lines at the above-mentioned other end for controlling a delay time of the signal propagating over the pair of signal transmission lines between the opposite ends of the pair of signal transmission lines.Type: GrantFiled: January 7, 1991Date of Patent: May 25, 1993Assignee: Hitachi, Ltd.Inventors: Keiichirou Nakanishi, Mararu Osanai, Minoru Yamada, Masakazu Yamamoto, Akira Masaki, Mitsuo Usami
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Patent number: 5208560Abstract: A signal transmission circuit including a signal line through which the signal is transmitted from a signal source element to a signal receiving element, a grounding line arranged along the length of the signal line, and a high impedance element connected between the grounding line and the ground.Type: GrantFiled: August 19, 1992Date of Patent: May 4, 1993Assignee: Fujitsu LimitedInventor: Nobuyuki Yasutake
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Patent number: 5157361Abstract: The present invention comprises a novel semiconductor device which further comprises a nonlinear transmission-line structure. The semiconductor device is that of a very long narrow voltage-dependent capacitor, such as a semiconductor diode or MOS capacitor, where the anode and cathode electrodes comprise the conductors of a transmission line and the depletion region comprises the dielectric of the transmission line. An input signal is applied at one end of the long, narrow structure. Such signal application results in the launch of a traveling wave traveling along the transmission-line structure. At the far end of the transmission-line structure, the signal is coupled out and applied to a load. The temporal and spatial modulation of the depletion capacitance of the semiconductor device as the traveling wave travels along the transmission-line structure results in temporal compression of the input signal.Type: GrantFiled: May 10, 1991Date of Patent: October 20, 1992Inventors: Michael E. Gruchalla, David C. Koller
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Patent number: 5148129Abstract: A laser-induced switch and a multiple cavity configuration are disclosed for producing high power microwave pulses. The microwave pulses are well controlled in wavelength and timing, with a quick rise time and a variable shape and power of the pulse. In addition, a method of reducing pre-pulse leakage to a low level is disclosed.Microwave energy is directed coherently to one or more cavities that stores the energy in a single mode, represented as a standing wave pattern. In order to switch the stored microwave energy out of the main cavity and into the branch waveguide, a laser-actuated switch is provided for the cavity. The switch includes a laser, associated optics for delivering the beam into the main cavity, and a switching gas positioned at an antinode in the main cavity. When actuated, the switching gas ionizes, creating a plasma, which becomes reflective to the microwave energy, changing the resonance of the cavity, and as a result the stored microwave energy is abruptly switched out of the cavity.Type: GrantFiled: June 20, 1991Date of Patent: September 15, 1992Assignee: The United States of America as represented by the United States Department of EnergyInventor: Paul R. Bolton
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Patent number: 5118969Abstract: A high power multiple pulse generator includes a plurality of transmission line sections, adjacent sections of which are coupled together by a saturable inductor. One transmission line section is switchably connected to a load impedance through an output switch. With the output switch open, the coupled transmission line sections are charged to a desired voltage potential. A burst of multiple pulses is generated by closing the output switch, causing the charge on the transmission line section connected to the load through the closed switch to be delivered to the load as a first pulse. This first pulse has an amplitude equal to one half of the charging potential and a duration that is a function of the length of the transmission line section. Once this first pulse is delivered to the load, a voltage is developed across the saturable inductor coupling the discharged transmission line section with an adjacent charged transmission line section, causing current to flow therethrough.Type: GrantFiled: February 9, 1990Date of Patent: June 2, 1992Assignee: General AtomicsInventors: Hiroyuki Ikezi, John S. deGrassie
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Patent number: 5087900Abstract: An improved transmission line network includes a transmission line connecting a signal source to a plurality of capacitive loads. Preferably, the transmission line is not terminated with its characteristic impedance. The transmission line may include capacitance added for the purpose of smoothing the rising or falling edge of signals distorted by reflections from the far end of the network. In addition, the transmission line network preferably includes resistance added in series with the transmission line for the purpose of dissipating reflections from the far end and thereby reducing distortion upstream from the series resistors. The capacitive loads may be connected to the transmission line through series resistors, the magnitudes of which are selected to obtain uniform rise or fall times at all loads.Type: GrantFiled: November 19, 1990Date of Patent: February 11, 1992Assignee: Reliability IncorporatedInventors: James R. Birchak, Wai-Leung Hon, Michael Ruhovets
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Patent number: 5066928Abstract: A pulse compressor for solitons includes a continuous dispersive non-linear propagation structure so constructed so that the wavefront of an individual soliton pulse is steepened. In addition, the pulse compressor has a continuously reduced time constant on a spatial, as opposed to a temporal basis. Various structures of the pulse compressor are described.Type: GrantFiled: May 2, 1990Date of Patent: November 19, 1991Assignee: General AtomicsInventors: Hiroyuki Ikezi, Yuh-Ren Lin-Liu, John S. deGrassie
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Patent number: 5043682Abstract: A printed circuit dispersive transmission line structure is disclosed comprising an insulator, a ground plane formed on one surface of the insulator, a first transmission line formed on a second surface of the insulator, and a second transmission line also formed on the second surface of the insulator and of longer length than the first transmission line and periodically intersecting the first transmission line. In a preferred embodiment, the transmission line structure exhibits highly dispersive characteristics by designing the length of one of the transmission line between two adjacent periodic intersections to be longer than the other.Type: GrantFiled: March 2, 1990Date of Patent: August 27, 1991Assignee: The United States of America as represented by the United States Department of EnergyInventors: Hiroyuki Ikezi, Yuh-Ren Lin-Liu, John S. DeGrassie
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Patent number: 5023574Abstract: Varactor diodes having noncommensurate parametric values are utilized within respective cells of a nonlinear transmission line. By the appropriate selection of varactor cell parameters, the configuration of a nonlinear transmission line can be improved to alleviate problems associated with varactor turn-on and punch-through voltage limitations, soliton compression and inefficient use of varactor nonlinearity, reflections from mismatched load and source impedances, and rining and soliton generation.Type: GrantFiled: April 17, 1990Date of Patent: June 11, 1991Assignee: Hewlett-Packard CompanyInventors: William J. Anklam, William E. Kunz
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Patent number: 5014018Abstract: There is disclosed herein a non linear transmission line comprised of a 50 ohm coplanar monolithic waveguide formed on top of a gallium arsenide substrate having a layer of lightly doped epitaxial gallium arsenide with a heavily doped buried layer, said epitaxial layer having spaced, electrically isolated islands. A self aligned Schottky diode junction is formed at the intersection of each isolation island with the center conductor of the transmission line. The second conductor of the transmission line is coupled through a contact window and an ohmic contact to the buried layer in each isolation island.Type: GrantFiled: October 6, 1987Date of Patent: May 7, 1991Assignee: Stanford UniversityInventors: Mark J. W. Rodwell, David M. Bloom
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Patent number: 4961059Abstract: A combined RFI filter and low pass filter includes two sections, both of which serve as both radio frequency interference filters and low pass filters, or dc integrators. Both sections have substantially equal time constants and employ non-polarized capacitors.Type: GrantFiled: May 6, 1988Date of Patent: October 2, 1990Assignee: RCA Licensing CorporationInventor: Mark R. Anderson
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Patent number: 4956568Abstract: A Monolithic Sampler is disclosed. The present invention overcomes the problem of inadequately low sampling rates that results from circuit designs or component limitations that constrain the bandwidths of previous instruments. The sampler includes five circuit stages: a local oscillator section that may be used to drive the system, a shock wave generator that produces high frequency edge-sharpened pulses, a reflection damping clamping section, a delay section, and a sampler section regulated by the stream of shock waves which produces an IF output. The local oscillator or a pulse generator (not shown) produces an input that propagates down a nonlinear transmission line. Once this input reaches the shock wave generator section, it encounters a series of hyperabrupt diodes which are employed as voltage dependent capacitors called varactors. These varactors deform the input pulses and generate a stream of spike-shaped waveforms known as shock waves.Type: GrantFiled: December 8, 1988Date of Patent: September 11, 1990Assignee: Hewlett-Packard CompanyInventors: Chung-Yi Su, Michael R. Ty Tan, William J. Anklam
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Patent number: 4875022Abstract: An high power microwave expander is provided which decreases the rise time of rf pulses. The expander is a transmission line in which internal conductors are separated and tapered to provide a spark gap with high isolation characteristics at low power. The arcing threshold of the spark gap can be adjusted by varying the internal pressure of the transmission line, injecting a gas such as helium into the transmission line and by providing free electrons in close proximity to the spark gap.Type: GrantFiled: March 28, 1988Date of Patent: October 17, 1989Assignee: The United States of America as represented by the Secretary of the ArmyInventors: Mark D. Berry, Robert J. Tan, Robert V. Garver
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Patent number: 4864258Abstract: A microwave rf envelope generator or pulse shaper has a main waveguide with two opposing branches connected in shunt to the main waveguide and are terminated with variable positionable shorts. The characteristic impedance of the shunted combination of the two branches equal one half the characteristic impedance of the main waveguide. An incident rf pulse applied to an input of the main waveguide is transmitted to a four way junction formed at the intersection of the two branches. The incident pulse is divided at the junction. Divided pulses are then transmitted down each of the branches and to an output of the main waveguide. The pulses traveling down each branch will have their phases shifted when they are reflected by the variable positionable shorts. The lengths of the branches are adjusted by the variable shorts so that the phase of the reflected and inverted pulses will cancel the trailing portion of the pulse transmitted out towards the output of the main waveguide.Type: GrantFiled: May 2, 1988Date of Patent: September 5, 1989Assignee: The United States of America as represented by the Secretary of the ArmyInventors: Robert V. Garver, Robert J. Tan
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Patent number: 4855696Abstract: A pulse compressor consisting of a loaded transmission line having a pluraltiy of sections which have a ratio of dispersion to nonlinearity that decreases in the direction of pulse transmission.Type: GrantFiled: December 9, 1987Date of Patent: August 8, 1989Assignee: Hewlett-PackardInventors: Michael Tan, Chung-Yi Su, William J. Anklam
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Patent number: 4833431Abstract: A triple resonance circuit is provided for improving the efficiency of high voltage pulses for pulse transformer applications. This circuit provides high transfer of energy when the normal mode frequencies of the coupled circuit are in the ratios of certain whole numbers.Type: GrantFiled: February 18, 1988Date of Patent: May 23, 1989Assignee: McDonnell Douglas CorporationInventor: Francis M. Bieniosek
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Patent number: 4823364Abstract: A receive coupler for a binary data communication system that transmits signals in rectangular waveform on a data bus (11) is provided. The receive coupler includes a transition and polarity detector (17) that differentiates received signals and produces an output pulse on one or the other of two output lines (21a and 21b) for each transition of the received signal, the output line being dependent upon the rise-fall direction of the transition. That is, rise transitions create pulses on one output line (21a) and fall transitions create pulses on the other output line (21b). The receive coupler also includes reconstruction logic (19) connected to the output lines of the transition and polarity detector (17) that reconstructs the receive signal based on the pulses. The pulses are created in the transition and polarity detector by two differentiator-comparator combinations.Type: GrantFiled: March 12, 1987Date of Patent: April 18, 1989Assignee: The Boeing CompanyInventor: Hans K. Herzog
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Patent number: 4812763Abstract: An electron spin resonance spectrometer comprises a resonator containing a sample and arranged in a magnetic field of constant strength and high homogeneity. A microwave bridge can be supplied with microwave energy in the form of an intermittent signal. Measuring signals emitted by the resonator are supplied to a detector and a signal evaluation stage. A line provided between a microwave source and the microwave bridge is subdivided into parallel pulse-shaping channels, one of them containing a phase shifter, an attenuator and a switch for the signal passing through the pulse-shaping channels. In order to be able to set, if possible, an unlimited plurality of pulse sequences for experiments of all kinds, the pulse-shaping channels are supplied in equal proportions from the line by means of a divider. All pulse-shaping channels are provided with a phase shifter and an attenuator. The pulse-shaping channels are re-united by means of a combiner arranged before the input of a common microwave power amplifier.Type: GrantFiled: November 20, 1987Date of Patent: March 14, 1989Assignee: Bruker Analytische Mebtechnik GmbH SilberstreifenInventor: Klaus-Dieter Schmalbein