FR2615337A1 - Heavy-current pulse generator - Google Patents

Abstract

Heavy-current pulse generator comprising at least one elementary cell 20 in series with an element to be controlled 10 between a DC voltage V and earth, this cell 20 being formed of a resistor 13 in series with a first break element 12 and with a resistive/capacitive element 11, in which each cell 20 comprises a line 14 with characteristic impedance Zo with one conductor connected to the common point between the resistor and the breaker element, and another conductor connected to earth, the resultant impedance of the resistive/capacitive element 11 in series with the element to be controlled 10 being equal to the characteristic impedance Zo. Application to the control of laser diodes.

Description

Pulse generator with high current.

 The invention relates to a high current generator, usable in particular for the control of laser diodes.

 The devices of the prior art make it possible to obtain forward-facing pulses. But because of the. capacity discharge, used in such devices, the back part of these pulses is not calibrated.

This is so in an article by Dr.Ing. Christophe Kulczuga, published in "Elektronika Poland" vol.24, nO 1-2, 38-45, 1983, coden
EKNTBZ ISSN: 0033-2089 and entitled "high frequency current pulse generators for the power supply of high power semiconductor lasers" which describes several types of current pulse generators and in particular a generator with solid-state transistors epitaxial planar avalanches having a four-stage structure, the storage capacities of all these stages discharging simultaneously through their common charge, which is a laser diode.

 The object of the invention is to overcome this drawback by delivering pulses having a substantially constant plateau followed by a steep rear edge.

 The invention proposes for this purpose a high-current pulse generator comprising at least one elementary cell arranged in series with an element to be controlled between a DC voltage V and the ground, this cell being formed of a resistor in series with a first switch element and with a resistive-capacitive element, characterized in that in each cell a characteristic impedance line Zo to a conductor connected to the common point input the resistor and the switch element and another conductor connected to ground, the resulting impedance of the resistive-capacitive element in series with the element to be controlled being equal to that the impedance Zo.

Such a generator makes it possible to deliver calibrated pulses adjustable in amplitude and in width,
More precisely, the first switch element is an avalanche transistor. The line is a line of type "stripline". Several elementary cells are mounted in parallel with each other, in series with the element to be controlled, each line being, in each cell, closed on its characteristic impedance by means of a second switching element which is an avalanche transistor, such as that we have the relation - t (t2 - t1 (+ @ t1 being the instant of closure of the first switch, t2 the instant of closure of the second switch, and the transit time in the line.

 Such a generator offers a great flexibility of control. For example, commands can be made with TTL logic levels.

 In the case where the element in question is a laser diode, most of the laser diodes having the cathode to the housing, it is possible here, advantageously, to put the housing to ground which avoids any parasitic radiation.

 Advantageously, the different cells in parallel can be formed of identical elements.

The characteristics and advantages of the invention will emerge from the following description, by way of nonlimiting example, with reference to the appended figures in which:
FIG. 1 is a schematic representation of the generator of the invention
FIG. 2 represents an embodiment of the generator of the invention using cells as illustrated in FIG. 1
FIG. 3 is a schematic representation of a variant of the generator of the invention
FIG. 4 represents an alternative embodiment of the generator of the invention using cells as represented in FIG. 3.

FIG. 5 represents an exemplary embodiment of a device implementing a pulse generator according to the invention
- Figures 6 and 7 illustrate the operating characteristics of the generator used in the device shown in Figure 5.

 As shown in FIG. 1, the laser diode 10 is connected in series with an elementary cell, between ground and a continuous supply voltage V. This cell is formed of element RC (resistance capacitance) 11, a switch 12, for example an avalanche transistor, and a resistor 13.

 A line 14, for example "stripline", of characteristic impedance Zo is connected to the common point between the resistor 13, which allows the charging of this line, and the switch 12.

 The laser diode 10 in series with the RC element has a resulting impedance equal to the characteristic impedance Zo.

 The switch operates in two stages in the open position: charging line 14 to the voltage + V through the resistor R in the closed position: discharging the line on the element RC 11 and the diode 10.

V
At point M a square signal of amplitude 2 and width 2 # is obtained, where # is the transit time in the line.

 The invention allows the paralleling of several cells 20A, 20B ... 20N as shown in Figure 2 so as to increase the current supplied to the element to be controlled.

 The switches of these cells are made for example by avalanche transistors 15A, 15B ... 15N.

 The control means of these transistors, known to those skilled in the art, have not been shown here. They can be made for example by a pulse generator connected to the bases of all transistors 15A, 15B ... 15N via pulse transformers.

By closing with a second switch 22 the second end of the line of FIG. 1 on an impedance 21 equal to its characteristic impedance Zo, at a given instant t2, it is possible to obtain an adjustment of the width of the signal obtained. at point M, with
Z: transit time in the line,
tl: instant of closure of the first switch 12,
t2: instant of closure of the second switch 22.

we obtain a pulse width:

<tb><SEP> 2 <SEP> = <SEP> 2 <SEP> t2 (t2 <SEP> + <SEP> - <SEP> t1) <SEP>
<tb> 2 <SEP>#<SEP>'<SEP> = <SEP> 2 <SEP> [t2 <SEP> - <SEP> t1 <SEP># (t2-t1)
<tb> 2 such a pulse has the following limitations
- lower limit
: O
: = t1 -
If t2 starts at an offset time of transit time before ttt the line is "shortened entirely", there are no more pulses,
- upper limit
2 = 3
2 # = # + t2 -t1
2 = t2 - t1
The line is whole.

The following relation must therefore be realized:
- (t2 - t1 <+ z
A concrete realization can be the following
2 line = 10 ns
t2 - t1 '6 ns
After 6 ns - there remains 4 ns to the propagation from the first switch 12 to arrive at the end of line, - the propagation from the second switch 22 starts in the direction of 12.

 At the end of 6 + 2 ns: Encounter of the two propagations, - the propagation resulting from 12 retraces path, - the propagation resulting from 22 retraces path.

 At this point, everything happens as if the line was open.

In other words, the line is artificially shortened by 2 ns 2 '= 6 + 2 ns = 8 ns so we have a pulse width
2 2t = 16 ns
As shown in FIG. 2 with cells such as shown in FIG. 1, several cells of FIG. 3 can be connected in parallel to produce the device of FIG. 5. It is then possible to obtain at the terminals of the laser diode 10 a pulse with variable amplitude, for example from 20 to 30 amps, of variable width, for example from 5 to 15 nanoseconds, with steep front and rear fronts, for example less than 5 nanoseconds.

 Most of the laser diodes having the cathode to the housing, such a circuit gives the possibility of putting the case to ground which avoids any parasitic radiation.

 We can choose a current that is a function of the number of cells and the value of the voltage.

The device represented in FIG. 5 comprises - a logic control 31 - a preamplifier 32; a generator according to the invention 33
The logic control performed in TTL circuits allows either an internal control with an oscillator 34 ranging from 10 to 20 KHZ, or an external control in one shot (35) or with a generator (36) not shown in the figure. Two monostable 37 and 38 triggered on the same front develop signals of width L for monostable 37, adjustable width L-2 to L + 2 for monostable 38. The control pulses are created on the rear edge of these signals of the as shown in FIG.

 The preamplifier 32 allows isolation between the logic and the generator 33 and gives it a sufficient level of energy.

This generator 33 consists of two drive transistors T7 and
T2 operating in avalanche. These transistors have their collectors respectively connected primary primary common pulse transformers 19 and 20, the secondary side of which attack the actual generator constituted here by way of example of five cells A, B, C, D,
E.

 These cells are cells of the type shown in FIG. 4, the first and second switches of which are avalanche transistors 15 and 25. Lines 14 are here of the "stripline" type arranged "sandwiched" one above the other for to form a multilayer component 18. In this component every other line is connected to ground.

 The windings 19A, 19B ... 19N, and 20B ... 20N arranged between the bases and the emitters respectively of the first 15 and second 25 transistors, and respectively coupled to two lines on which pulses are sent at times t1 and t2 allow to switch respectively these first transistors 15 at time t1 and these second transistors 25 at time t2.

 The two outer faces of the multilayer "stripline" 18 are grounded to avoid any parasitic radiation.

If the generator as commanded in FIG. 5 is used in a mounting as shown in FIG. 7, a signal 41 as illustrated is obtained on the avalanche photodiode 40, the characteristics of which are as follows:
Amplitude: 20 to 25A
Width: 0 to 15 ns.

fronts: <2 ns
Frequency: 0 to 20 Khz more particularly here we have
front edge. or735 ps
backside n / 1,69 ns
tray width ^ 210 ns
It is understood that the present invention has been described and shown only as a preferred example and that its constituent elements can be replaced by equivalent elements without departing from the scope of the invention.

 Thus the element to be controlled using the generator of the invention may be an element other than a laser diode.

 Thus the other elements used can be replaced by elements having similar characteristics.

 In the various figures, the lines have been represented in the form of coaxial lines, but they may be, just as well, parallel multilayer "stripline" lines. Such an embodiment then makes it possible to vary the current on the bearing of the pulse by modifying the width of the central conductor of the striplines.

 The different cells of the generators shown in FIGS. 2 and 4 can, of course, be formed respectively of identical elements.

Claims (10)

1 / high current pulse generator comprising at least one elementary cell (20) in series with a control element (10) between a DC voltage (V) and the ground, this cell (20) being formed of a resistor (13) in series-with a first switch element (12) and with a resistive-capacitive element (11), characterized in that in each cell (20) a line (14), with characteristic impedance Zo, has a connected conductor at the common point between the resistor (13) and the switch element (12), and another conductor connected to ground, the resulting impedance of the resistive-capacitive element (11) in series with the element to be controlled ( 10) being equal to the characteristic impedance Zo. 2 / Generator according to claim 1, characterized in that a plurality of elementary cells (20A, 20B - 20N) are mounted in parallel with each other, in series with the element to be controlled (10). 3 / generator according to any one of the preceding claims, characterized in that in each cell line (14) is closed on its characteristic impedance Zo through a second switch element (22). 4 / generator according to any one of claims 2 or 3, characterized in that in each cell there is the relationship - - tl (+; tl being the instant of closure of the first switch, t2 the closing time of the second switch, and 2 the transit time in the line. 5 / generator according to any one of the preceding claims, characterized in that the switch elements (12, 22) are avalanche transistors (15, 25). 6 / Generator according to any one of the preceding claims, characterized in that the lines (14) are of type "stripline". 7 / Generator according to claim 4, characterized in that striplinen type lines are arranged one above the other to form a multilayer component (18). 8 / Generator according to claim 7, characterized in that the two outer faces of this multilayer component are connected to ground 9 / Generator according to any one of claims 5 to 7, characterized in that windings (19, 20). are arranged between the base and the emitter of each transistor, these windings being respectively coupled to two lines on which pulses are sent at times t1 and t2. 10 / Generator according to any one of the preceding claims, characterized in that the element to be controlled (10) is a laser diode. 11 / Generator according to any one of claims 2 to 10, characterized in that the cells (20A, 20B ... 20N) are all formed of identical elements.