The present invention relates in general to pulse generators. More specifically, the present invention relates to bipolar pulse generators that provide a high power/energy pulse on a load.
Recent trends in the development of pulse power microwave sources for a variety of applications have been directed to increasing power, efficiency and energy on the load. Transmission line pulse generators with different kinds of fast switches, including light activated photoconductors, can achieve some of the best results in generating high power short duration pulses. For a given limited charging voltage of transmission lines defined by high-current switches, high powered and high energy density transmission lines imply low characteristic impedances. This low range of characteristic impedances, however, frequently causes problems for coupling with typically used load impedances, 50 ohm or higher, for example, radiating impedances, which introduces a problem with efficient high ratio impedance transformation.
Bipolar pulse generators very often have significant advantages compared to unipolar pulse generators, with just one example being UWB radiation. Further, there are many potential applications of bipolar pulse generators, for example in industry, physics and medicine, where very often bipolar pulse generators with time separation between positive and negative sub-pulses are preferable or required. Today, however, there are only various types of high power and high energy unipolar pulse generators (Marx generator and stacked Blumlein generator in various modifications).
For example, a high energy Marx generator with coaxial cable to provide rectangular unipolar pulse is known and described in “A PFN Marx Generator Based on High-Voltage Transmission Lines”, by S. M. Turnbull et al. presented in Meas. Sci. Technol. 11 (2000) N51-N55. Further, a stacked Blumlein generator with a single switch has been proposed in U.S. Pat. No. 2,769,101 issued to R. D. Drosd. This type of generator has been designed and presented in various publications including, for example, “Modeling of Wound Coaxial Blumlein Pulsers”, by Jose O. Rossi et al:, published in IEEE Transactions on Plasma Science”, Vol. 34, No. 5, October 2006, “Design of a 150 kV, 300A, 100 Hz Blumlein Coaxial Pulser for Long Pulse Operation”, presented in IEEE Transactions on Plasma Science”, Vol. 30, No. 5, October 2002. Still further, some modifications of stacked (cascade) Blumlein generators are presented in “A Combined High-Voltage, High-Energy Pulse Generator”, by S. J. MacGregor et al. published in “Meas. Sci. Technol” 5 (1994), pp. 1580-1582, and “A Novel HV Double Pulse Modulator”, published in “Meas. Sci. Technol” 5 (1994), pp. 1407-1408. Finally, another type of high-power generator, namely, a “Multi-Stage Blumlein” is proposed by J. Yampolsky in US Patent Application 2005/0174715 A1, 2005. The content of each of the above-reference documents is incorporated herein by reference. All of the above-referenced generators produce only a unipolar pulse and do not provide voltage (impedance) transformation, with the exception of the proposed multi-stage Blumlein disclosed in US Patent Application 2005/0174715A1, which provides moderate transformation but requires a substantial number of switching devices.
A transmission line “High-Voltage Pulses Generator” has also been described in U.S. Pat. No. 1,098,502 A1 issued to Bosamykin V. S. et al, 1996, which provides bipolar pulse by a single switch. However, the power/energy on load is much less compared to that provided by the above-mentioned unipolar generators. In addition, impedance transformation in the device is low.
The applicant has also previously described a transmission line in U.S. Patent Application 2007/0165839 A1 entitled “Bipolar Pulse Generators With Voltage Multiplication”, which provides a device with a single switch with all of the required voltage/impedance transformation. However, in a stacked configuration with several switches, the energy provided by this type of generator is less compared to the above mentioned Blumlein-based stacked unipolar generators with less number of switches.
Accordingly, there remains a need for a bipolar pulse generator solution based on voltage charged transmission lines, which provides high power and high energy. Further, there remains a need for high power/energy bipolar pulse generator, which can provide voltage/impedance transformation. Still further, there remains a need for a high power/energy bipolar pulse generator with pulse separation between positive and negative sub-pulses.
It would be desirable to provide a bipolar pulse generator that could meet all of the above needs while being implemented in a simple structure, preferably with a single switch, and preferably in a high efficiency design that has a relatively low total size, while still allowing simple access by fibers to a closing photoconductive switch that actuates the bipolar pulse generator.
The present invention provides a bipolar pulse generator that can be implemented in a simple structure while providing a high efficiency design having a relatively low total size and still allowing access by fibers used to control a photoconductive switch that activates the generator.
In a preferred embodiment of the invention, a bipolar pulse generator includes a stacked Blumlein generator structure with an additional transmission line connected to a load at its near end and short-circuited at its distal end. An extra transmission line is positioned between the Blumlein generator's structure and the load provides specified limited gap between positive and negative sub-pulses.
According to a further preferred embodiment of the present invention, the bipolar pulse generator further includes a bended Blumlein generator structure, in which an existing intrinsic “stray” transmission line is used to provide the bipolar pulse.
According to a still another embodiment of the present invention, the bipolar pulse generator consists of stepped transmission line with additional switches positioned between steps, which are charged by different voltages.
The bipolar pulse generator according to the invention generates high power/energy pulses in a compact design with access to fibers for activating photoconductor switches. Bipolar pulse generators according to the invention are useful for HPM generation, in particle accelerators and in other high voltage physical, industrial, medical and test instruments.
Other features, uses, advantages, embodiments, etc. of the invention will become apparent to those skilled in the art from the following detailed description of the preferred embodiments of the invention.
The invention will be described with reference to certain preferred embodiments thereof along with the accompanying figures, wherein:
a depicts a schematic of transmission line Marx-based bipolar pulse generator according to an embodiment of the present invention;
b depicts a pulse shape on the load of generator shown on
a depicts a schematic of an n-stacked Blumlein based bipolar pulse generator according to an embodiment of the present invention;
b depicts a pulse shape on the load of generator shown on
a depicts a schematic of a double Blumlein-based bipolar pulse generator according to an embodiment of the present invention;
b depicts a pulse form on the load for generator according to
a depicts a schematic of a double Blumlein-based bipolar pulse generator with their intrinsic transmission lines according to an embodiment of the present invention;
b depicts a pulse form on the load for generator according to
a depicts a schematic of two series connected double Blumlein based bipolar pulse generators with their intrinsic transmission lines according to an embodiment of the present invention;
b depicts a schematic of two series connected double Blumlein based bipolar pulse generators in case of neglecting of intrinsic transmission lines according to an embodiment of the present invention;
a depicts a schematic of double single-stage bipolar pulse generator with their intrinsic transmission lines that provides a bipolar pulse without a gap between sub-pulses according to an embodiment of the present invention;
b illustrates the pulse form on load for generator according to
a depicts a schematic of two-step, double bipolar pulse generators with their intrinsic transmission lines according to an embodiment of the present invention;
b illustrates the pulse form on the load provided by the generator according to
a depicts a totally folded design of N-step bipolar pulse generator with two switches in first two successive steps and with the gap between sub-pulses equal to the length of sub-pulse according to an embodiment of the present invention; and
b depicts a partial-folded design of N-step bipolar pulse generator with two switches in first two successive steps and with the gap between sub-pulses equal to the length of sub-pulse according to an embodiment of the present invention
a is a schematic of Marx-based transmission line bipolar pulse generator according to an embodiment of the present invention. The generator may consist of any number (n) of identically charged transmission lines 10. Each transmission line 10 is connected to a corresponding individual switch 11 and to a corresponding individual charging element 12 (resistor R or inductance L). Instead of typical direct connection to the load 15, the load 15 is connected through an additional transmission line 13 of a specified length. In addition, a transmission line 14 is connected to the load 15 at its near end and is short-circuited at its distal end. The electrical length of the transmission line 14 is equal to the sum of length of each charged line 10 and the length of line 13. The described arrangement provides a specified gap between positive and negative sub-pulses that is equal double the transit time of transmission line 13.
In operation, all of the charged transmission lines 10 are charged by their individual charging element 12. Once all the charged transmission lines 10 are fully charged, all of the switches 11 are closed at the same moment of time, thereby causing the charged transmission lines 10 to operate as n series connected generators. As a result, a bipolar pulse with a predicted time space or gap between positive and negative sub-pulses is realized on the load 15 as is illustrated in
a is a schematic of a stacked Blumlein-based bipolar pulse generator according to an embodiment of the present invention. The generator consists of a charging structure 30 with any number n of identically first charged transmission lines 31 with switches at their near ends, and n oppositely charged second transmission lines 32 with the same length and characteristic impedances as for the first transmission lines 31. The output of this stacked Blumlein structure 30 is connected to the near end of an additional non-charged transmission line 33 with a specified electrical length t1 and characteristic impedance equal to 2nZ0, where Z0 is a characteristic impedance of each charged first transmission lines 31 and the second transmission lines 32. The load 34 is connected to the distal end of the transmission line 33. In addition, another transmission line 35 is provided, which is connected to the load 34 at its near end and is short-circuited at its distal end. The load impedance is equal to nZ0, while the characteristic impedance of transmission line 35 is the same as for transmission line 33. The electrical length of the transmission line 35 is equal 2t+t1, where t is electrical length of each of the first transmission lines 31 and the second transmission lines 32.
During operation, all the transmission lines 31 and the transmission lines 32 are charged by a voltage supply V0. All of the n switches are then closed simultaneously and a wave propagation process occurs. Identical waves propagate on all of the charged transmission lines 31 and the same is true for all of the charged transmission lines 32. The resulting pulse on the load is illustrated on
Referring to
a is a schematic of a double Blumlein based bipolar pulse generator according to an embodiment of the present invention. This generator consists of a known double Blumlein unipolar pulse generator structure (transmission lines 60, 61, 62 and switch 63) with additional transmission lines 64 and 65. A transmission line 64 with time delay t1 is connected between the output of the double Blumlein unipolar pulse generator structure and a load 66. Transmission line 65 is connected to the load 66 at its near end and is short-circuited at its distal end. A characteristic impedance of the transmission lines 64, 65 is twice the impedance of the load 66 and four times more then the impedance of each of the transmission lines 60, 61 or 62. The electrical length of the transmission line 65 is twice the length of transmission lines 60 or 61 and is equal to the length of transmission line 62. Line 62 could also be separated in the middle by two identical length transmission lines without any change in operation and in pulse form on the load 66.
Ideal operation of this generator is similar to that for generator according to
Referring to
It should be noted that combined design of
a is a schematic of a series connected two double Blumlein based bipolar pulse generators according to an embodiment of the present invention. This generator consists of a double Blumlein-based bipolar pulse generator's structure (transmission lines 80, 81, 84, 86 and 88), which is the same as the generator on
By analogy with the generators shown in
a is a schematic of double single-stage bipolar pulse generator according to an embodiment of the present invention. By analogy with the double Blumlein-based bipolar pulse generators according to
b illustrates pulse shape on the load 125 independent on values Z1 and Z2. In the case when Z1 and Z2 are very high (Z1, Z2>>Z, i.e. intrinsic lines 123 and 124 are neglected), the bipolar pulse according to
Referring to
In the case when impedances Z1 and Z2 of intrinsic transmission lines 136, 137, 138 and 139 are much more compared to Z (and 3Z) the structure
a is a schematic of bipolar pulse generator as an embodiment of the present invention. This generator consists of two-step, double single-stage bipolar pulse generator structure with intrinsic transmission lines that provides bipolar pulse. This generator operates, in principle, as generator according to
During operation if switch 164 is turned ON (closed) at time t0, the second switch 165 should be turned ON (closed) at time t0+t, i.e., at time slightly less than t after t0 to prevent overvoltage on switch 165. However, in the case of switch 165 is a spark-gap it will be turned ON automatically due to overvoltage. The impedance transformation (ZL/Z) as a ratio of load impedance 167 to the lowest impedance Z of the first step 160 and ratio of inductive stub 166 to the load impedance will be increased by increasing the number of steps without deterioration the pulse shape.
a and 21b illustrates folded and partly folded designs of bipolar pulse generator according to
The invention has been described with reference to certain preferred embodiments thereof. It will be understood by those skilled in the art that modifications and variations are possible with the scope of the appended claims.