专利汇可以提供Narrow ultra wideband pulse generator专利检索,专利查询,专利分析的服务。并且A circuitry for generating a narrow impulse including an input device coupled to a matching circuitry that is coupled to a step recovery diode (SRD). The input device is configured to receive a succession of digital input signals, each characterized by having high level and low level portions. The signals having less than 50% duty cycle. The input device is configured to drive forward the SRD through the matching circuitry during the high level portion of the digital signal, whereby the SRD stores sufficient power for generating the narrow impulse following the falling edge of the high level portion of the digital input signal.,下面是Narrow ultra wideband pulse generator专利的具体信息内容。
The present invention is in the general field of generating narrow (ultra wideband) impulses for use in various ultra wide-band applications such as through the wall imaging applications, etc.
Narrow (wideband) impulses for use as a driving signal(s) for various applications is generally know per se. Typical examples are, for instance, UWB communication, radar such as through the wall imaging, Comb generator, frequency multipliers, etc.
A generalized block diagram illustrating a typical impulse (comb) generator application is illustrated in
In operation, the SRD can store charge during the positive half of an input sinusoidal signal and then to extract that charge during the negative going half cycle. Consequently, a current pulse with a rise time equivalent to the “snap time” of the diode is generated in the impulse circuit of the pulse generator or comb generator (multiplier). The so generated signal can then be coupled to the desired application.
Bearing this in mind, attention is drawn to
As shown, the circuitry 11 includes a class A power amplifier 12 amplifying an input sine wave and driving known per se matching circuit 13 which is coupled to SRD 14. The positive half of the input sine wave (21 in
Note that in order to drive sufficient current into and out of the SRD (e.g. 14 of
There is thus a need in the art to provide a more efficient circuitry for generating narrow ultra wideband pulses.
The invention provides for a circuitry for generating a narrow impulse, comprising an input device coupled to a matching circuitry that is coupled to a step recovery diode (SRD); the input device is configured to receive a succession of digital input signals, each characterized by having high level and low level portions, the signals having less than 50% duty cycle; said input device is configured to drive forward the SRD through the matching circuitry during the high level portion of said digital signal, whereby said SRD stores sufficient power for generating said narrow impulse substantially following the falling edge of the high level portion of said digital input signal.
Still further, the invention provides for a circuitry for generating a narrow impulse, comprising an input device coupled to a matching circuitry that is coupled to a step recovery diode (SRD); said input device is responsive to said input signal and is capable of driving forward the SRD for a minimal duration for storing sufficient power, for generating narrow impulse.
For a better understanding, the invention will now be described by way of example only, with reference to the accompanying drawings, in which:
FIGS. 6A-B illustrates a sequence of simulated waveforms associated with the circuitry of
Attention is now directed to
Turning now to
Reverting now to
An inverted digital input pulse 46 is AC coupled to the bottom transistor 32. Due to the AC coupling, the transistor turns on for a very short time (47) at the end of the pulse (46). Note incidentally that signal 46 substantially terminates at the end of input signal 41.
As a result, current through the inductor 36 and SRD 33 reverses and flows towards the negative supply (through SRD 33, inductor 36 and the turned on transistor 32). This negative peak immediately follows the positive current pulse (see chart I of
Once the charges are depleted from the SRD 33, the current flow stops abruptly (see the falling edge of the negative pulse in chart I) and consequently (in compliance with the L di/dt stipulation) a very short negative high impulse is generated over the inductor (see the negative waveform 44) with the capacitor (35) providing return to ground. This pulse constitutes the ultra wide band narrow pulse. The pulse is then AC coupled to the load (see waveform 45).
Note that the duration of the input digital signal (by the latter example 15 nano sec), can be configured experimentally such that sufficient charges will be stored in the SRD for allowing the generation of the narrow impulse of interest.
The invention is not generally bound by the specific circuitry depicted in
Attention is now drawn to
The circuitry of
Turning now to the structure and operation of the pre-circuitry in accordance with an embodiment of the invention, a Logic 0 to 5V signal at pulse repetition frequency of say 1 to 12 MHz drives an input buffer inverting gate U1 56. The gate feeds an AND gate U2 57 and an inverting gate of U3-B 58. The inverting gate U3-B 58 feeds a 13 nano second delay circuit comprising R2, L3, C9, and C10. The latter components implement a filter and perform delay to the pulse. U2 57 performs AND function of the signal out of U1 56 and a delayed version of the signal. The output of U2 57 is a positive logic 5V pulse with duration of about 15 nano second, constituting the digital input signal. The pulse out of U2 57 feeds the base of a high speed emitter transistor Q1 151. As specified above, the input signal width and the repetition rate thereof would affect the duty cycle of the input signal.
Having described the structure and operation of a pre-circuitry in accordance with an embodiment of the invention, the operation of the circuitry for generating the ultra wideband pulse will now be briefly described. Thus, similar to what has been described in a generalized fashion with reference to the embodiment of
Revering for a moment to the pre-circuitry, the pulse out of U2 57 feeds an inverting gate U3-A 58. The inverted pulse at the gate output (58) goes through a capacitor C9 503 and base resistor R4 504 to feed the base of a high speed, high current transistor Q2 52. The rising edge of the base current pulse coincides with the end of the current flow through the SRD D1 54.
Bearing this in mind, attention is drawn again to the operation of the circuitry for generating the narrow impulse. Thus, as explained also with reference to
As readily arises from the foregoing discussion, the circuit is driving current into the SRD for a duration that is long enough to store sufficient charges (in the SRD), which would eventually lead to the generation of the desired output narrow impulse. The short duration of the digital input pulse would render the circuitry efficient insofar as power consumption is concerned. As specified above, the power consumption is dependent also upon the repetition rate of the pulse which, together with the pulse width, constitute the input signal duty cycle.
Those versed in the art will readily appreciate that the invention is not bound by the specific structure and operation of
Attention is now drawn to FIGS. 6A-B illustrating simulated waveforms associated with the circuitry of
The input transistor 31 is driven by a digital input signal. As shown, the digital input signal that drives transistor is a digital short positive pulse 64 (shown in
Reverting now to
During the short duration of the forward current, the SRD stores charge. The positive current is illustrated in chart I1 (
An inverted digital input pulse 62 is AC coupled to the bottom transistor 32. Due to the AC coupling, the transistor turns on for a very short time (61) at the end of the pulse (64).
As a result, current through the SRD 33 reverses and flows towards the negative supply through the turned on Q2. This negative peak current (depicted as 601 in chat I1 of
Once the charges are depleted from the SRD 33, the current flow stops abruptly (see the falling edge 602 of the negative pulse in chart I1 in
Note that the invention can be used in numerous applications. Typical, yet not exclusive, examples are comb generator, multiplier, radar as through the wall imaging, UWB communication.
The invention has been described with a certain degree of particularity, but those versed in the art will readily appreciate that various alterations and modifications, maybe carried out without departing from the scope of the following Claims:
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