FR2486333A1 - Integrated injection logic time-base oscillator circuit - uses constant current source and large switched current to produce large swing linear sawtooth voltage across capacitor - Google Patents

Abstract

The oscillator consists of a capacitor and an integrated current injection logic module. It contains a transistor which forms a switch with a current input from a current source whilst the emitter is connected to a common point (5). One injection logic module (A) is connected to the output of a controlled current generator along with the capacitor (10). The common point (5) is connected to the negative supply through a resistor (R1). The current generator consists of a fixed current generator (14) a current mirror (T4,T5). The control transistor is connected to the common point or to a potentiometric tap on the supply resistor. Other modules are connected in the circuit to produce a relaxation oscillator or monostable with a linear sawtooth voltage across the capacitor with a wide voltage swing. The logical and analogue components are realised using the same technology. The time base circuit is used to use two current generators one giving a fixed current and the other a much larger current. The larger one is switched on and off to periodically charge and discharge the capacitor with a sawtooth voltage.

Description

"INTEGRATED CIRCUIT DEVICE CONSTITUTING AN OSCILLATOR
IN ASSOCIATION WITH A CAPACITOR "
The invention relates to an integrated circuit device constituting an oscillator in association with at least one capacitor, and comprising at least one module, of the type used in the logic technique known as current injection, module associating a transistor, which constitutes at least a switch, to a current source provided with a current output, while the emitter of said transistor is connected to a point called common point.

 This device is used by the electronics industry to produce time bases.

 Said module is known in the prior art since it is the basic element of logic circuits in the technique known as current injection, or abbreviated I2L (that is to say in English, Integrated Injection Logic), the lateral transistor said injector in this technique, here forming said current source.

 Such circuits are known in particular from French patent 2,316,804 which describes a device with integrated logic injection circuits in which threshold functions are used. These threshold functions are used to make the logic according to which the conduction states of the switching transistors are determined more complex. But the achievable functions remain in the domain of logical functions.

 The object of the invention is to provide a linear circuit, in particular a relaxation or monostable oscillator, which takes advantage of the advantages inherent in so-called I2L logic integrated circuits, namely their high integration density and their very low consumption.

 The invention is based on the basic idea of using two generators, produced in so-called I2L technology, one of which provides a given current and the other a larger current, and of combining them with means so that the two currents subtract from each other, while the larger of the two is periodically removed. This produces a current source which changes direction periodically, in order to generate a sawtooth voltage across the terminals of a capacitor.

 To this end, the device according to the invention is notably remarkable in that it associates at least a first of said modules with a controlled current generator, the current output of said first module being connected to one of the terminals of the controlled current generator. , and also to a connection for the connection to said capacitor.

 This arrangement offers the advantage of using, as a current generator to create a voltage ramp across the terminals of a capacitor, a module of the so-called I2L type which can be integrated and whose consumption is extremely low.

 The device according to the invention is advantageously produced in such a way that said common point is connected to a first supply terminal of the circuit via a resistor.

 In general, in the so-called I2L circuits, said common point is connected directly to ground. The embodiment according to the invention allows a much greater voltage excursion across the terminals of the capacitor.

 Advantageously, the controlled current generator consists of an assembly comprising a fixed current generator coming from a second power supply terminal of the circuit, a control transistor and a current mirror, and the transmitter of the control transistor is connected to said fixed current generator while its collector is connected to the input of the current mirror, the output current of which forms the current of said controlled generator.

 This arrangement offers the advantage that said fixed generator is achievable in so-called I2L technology, that is to say that it can stably supply very low currents and be integrated in a very small footprint.

In a variant, the device according to the invention is remarkable in that the base of said control transistor
is connected to said common point
This variant represents the simplest way to fix the potential of the base of said control transistor.

 In another variant, the device according to the invention is remarkable in that the base of said control transistor is connected to a potentiometric tap of said resistor.

 This variant makes it possible to use any geometry for the control transistor, since the base-emitter voltage is not imposed, since it is possible, depending on its value, to choose the point where the voltage is taken from said resistor.

The control device of said controlled current generator is advantageously produced by associating a second and a third of said modules, the current output of the second module being connected both to a switch of the third module and to a switch of said first module while the current output of the third module is connected to a switch of the second module
and that the emitter of said control transistor is also connected to at least one switch of the second module.

 This embodiment offers the advantage that, in the same technology, it is possible to produce logic elements controlling the current generator, and analog elements such as the current sources linked to the capacitor.

 In a particular embodiment, the device according to the invention is remarkable in that it further comprises a zener diode, a fourth and a fifth of said modules and in that a switch of said fourth module is connected to the output of current of said third module, while a switch of the fifth module is connected to the current output of the fourth module, its own current output being connected to one terminal of the zener diode whose other terminal is connected to the neck output rant of said first module.

 This embodiment makes it possible to trigger the control device of the current generator in a precise manner, in particular by using two additional modules always produced in the same technology called I2L.

In a variant of this embodiment, the device according to the invention is remarkable in that it further comprises a fourth of said modules and two transistors mounted in differential pair, one of the transistors of this pair having its base connected to the current output of the above first module and its collector connected to the current output of said fourth module, while a switch of this same fourth module is connected to the current output of the above third module
The advantage of this variant is that it makes it possible to adjust in operation the frequency and the amplitude of the oscillator, by means of an external voltage.

 Finally, in the case of a monostable oscillator, the device according to the invention advantageously further comprises a sixth and a seventh of said modules, connected in cascade and inserted in the connection which connects the current output of the said third module to a switch. of the above fourth module, and it also comprises an eighth module, a switch of which is connected to the current output of the sixth module.

 This arrangement offers the possibility of inhibiting the command of the third module and thus very easily transforms a relaxation oscillator into a monostable oscillator.

 The description which follows, with reference to the appended drawings describing nonlimiting examples, will make it clear how the invention can be implemented.

 Figure 1 shows the electrical diagram of an integrated circuit module.

 FIG. 2 represents a block containing a said module.

 Figure 3 shows a fixed amplitude relaxation oscillator.

 FIG. 4 represents a relaxation oscillator with adjustable amplitude.

 FIG. 5 represents an arrangement which transforms the oscillator of FIGS. 3 or 4 into a monostable oscillator.

 The figure shows, for the record, a module, of the type used in the technique known as current injection, module associating a transistor 2, which constitutes at least one switch, with a current source provided with a current output E, source of current constituted by the transistor 1. The transistor 2 is capable of having several collectors 13, and therefore of constituting several switches in parallel. Terminal E allows both the current output of transistor 1 and the control of transistor 2, by giving access to its base.

 The diodes 3 represent the electrical equivalent of the emitter-base junction of the transistor 1, and indicate that all of the said junctions are connected in parallel between the same lines V + and 5.

 Thus, all the emitters of the transistors 2 are also connected to the same point 5, called the common point.

 FIG. 2 is intended to clarify the understanding of FIG. 3 by showing what is contained inside the rectangular blocks of said FIG. 3. The transistors 1 and 2 are, of course, the same as in FIG. 1, and the orientation of this block will always be the same in the following figures, that is to say that we will always have the V + current input at the top in transistor 1, on the left the connection (s) 6 to the or the switches, below the switch transmitter connection 5, and to the right, marked with a small circle, the terminal E for current output and switch control.

FIG. 3 which represents a fixed amplitude relaxation oscillator, shows in particular that said common point 5 is connected to a first supply terminal V- of the circuit via a resistor Ri. This resistance determines a certain global current which is distributed between the emitters of the various transistors 1 of FIG. 1, (also symbolized by the diodes 3 of the same figure). Since these are integrated, they have very similar characteristics and the current is therefore distributed in a substantially equal and constant manner between all the junctions of PNP transistors of the same dimension, which can therefore play the role of current sources. This behavior is known and used in I2L logic. But we usually connect point 5 to ground and place the resistor Ri between the current inputs of the modules and the positive supply V +. The potential of terminal E is then limited upwards by the voltage VBE of the switching NPN transistor, and downwards by the ground, whereas on the contrary with the arrangement adopted, the potential is only limited downwards by the breakdown voltage of the base-collector junction of the switching transistors, which allows a voltage excursion from point E of the order of 6 to 7 volts, instead of less than one volt.

The device shown associates at least a first
of said modules to a controlled current generator 12, the
current output of said first module A being connected to
one of the terminals of the controlled current generator, specified
ment to the collector of transistor T5, and also to a
connection of connection to said capacitor 10. This condensa
tor is provided outside and therefore the integrated circuit
has only one connection connected to an output terminal
tie 11 for connection to the capacitor. A resistance of
protection is inserted in this connection.

In the example shown, the current sources of the
said modules are dimensioned to deliver a current i
and the controlled current generator 12 is dimensioned for
generate a current 3i.

Under these conditions, when the current generator
12 is in action, a current 3i flows to the transmitter of the
transistor T5 while a current i exits through the output of
current of module A. By difference, a current2i must
flow through capacitor 10 going from V + to the
T5 collector.

 When, on the other hand, the current generator is cut, the current i coming from the module A, must flow in the capacitor going towards V +. There is therefore alternately in the capacitor a current 2i in one direction and a current i in the other direction, which causes the appearance of a sawtooth voltage whose slope is double the other.

 It is easy, when designing the circuit, to choose the dimensions of the current generating transistors to obtain the desired slope ratio.

 Furthermore, the controlled current generator consists of an assembly 12 comprising a fixed current generator 14 coming from a second power supply terminal of the circuit V + of a control transistor T3 and of a current mirror T4 , T5, the emitter of the control transistor T3 being connected to said fixed current generator and its collector being connected to the input of the current mirror, the output current of which forms the current of said controlled generator.

 The generator 14 is constituted by a transistor identical to those of the modules, that is to say a lateral PNP, but dimensioned to supply a current 3i. Its base is united in common point 5.

 The current 3i, when the transistor T3 opens the passage to it creates at the terminals of the transistor T4, mounted as a diode, a voltage such that, applied to the base of T5, it makes it absorb a current of the same value according to the process classic current mirrors.

 The device associates a second and a third of said modules, the current output of second module B being connected both to a switch of third module C and to a switch of said first module A, while the current output of third module C is connected to a switch of the second module B. The emitter of said control transistor 13 is also connected to at least one switch of the second module B. In other words, modules B and C are used according to a logic function and mounted in so-called R / S. Assuming that no external action is exerted, if the switch of B is conductive, the current of C flows there and therefore the switch of C is cut and does not absorb the current of B which holds the B conductor switch well. The reverse state is also stable.

 It is not necessary to insist on this conventional device. The connection between the current output of B and the switch of A makes it possible to force a "cut" state of the switch of B, when the switch of A is conductive.

The connection of a switch of B with the transmitter of
T3, and therefore also with the current generator 14, allows B to absorb the current from 14 when its switches are conductive. The corresponding switch must be of sufficient size to be able to absorb at least the current 3i.

 The base of the control transistor T3 can be connected to the common point 5. With respect to the injection transistors of the circuit whose emitter is connected to V + and the base at point 5, this transistor T3 has a lower voltage VBE, since minus the voltage across the generator 14. This consists of a saturated current injector transistor and therefore only causes a voltage drop of a few tens of millivolts. However, it is however necessary that T3 be of sufficiently large dimension to be able to flow current 3i with a base voltage reduced by the voltage across the terminals of generator 14.

 Another solution consists in connecting the base of said control transistor T3 to a potentiometric tap of said resistor R1. Thus, it is possible to have a higher voltage at the terminals of the base-emitter junction of T3, which makes it possible to reduce its dimensions.

 The device shown further comprises a zener diode as well as a fourth and a fifth of said modules.

A switch of said fourth module D is connected to the current output of said third module C however a switch of the fifth module E is connected to the current output of fourth module D, its own current output being connected to a terminal of the zener diode Z, the other terminal of which is connected to the current output of said first module A.

This system makes it possible to control the R / S flip-flop constituted by B and C so as to cut the current of the current mirror when the voltage across C reaches a value determined by the voltage of zener. ErS effect, as we saw above, there is a state in which the switch of B is cut, so that of C is conductive. For this, that of D must be cut, therefore that of
E is conductive, which supposes that it does not pass current in the zener diode. This is indeed the case at the start of charging the capacitor 10 since the potential on line 15 is then close to the supply voltage V +.

 The transistor T3 is then conductive, and therefore it passes a current 3i in T5, and a current 2i in the capacitor 10. The potential on line 15 then decreases then an instant occurs when the zener diode becomes conductive.

Then the state of the modules E, then D, then C reverses, i.e. the switch of C becomes cut, and therefore the switches of B become conductive and one maintains
C in its new state, while the other absorbs the current from generator 14 and shunts the base-emitter junction of T3, which blocks it.

 From this moment, T5 no longer absorbs current and the capacitor 10 begins to discharge under the action of the current i from A. It can be noted that, in all the conditions encountered, the current from A has always been absorbed, either by T5, or by the condenser, and that because of this fact the switch of A was always cut, therefore without influence on the rocker R / S.

 When, as a result of the discharge of the capacitor, the potential on the current output of A approaches that of the supply V +, the base-emitter junction of the switch transistor of module A becomes conductive and absorbs the current from the source of current from this module A.

As a result the capacitor ceases to discharge, and moreover the switch of A becomes conductive, causing that of B to become cut, releasing the current from generator 14, making the transistor T3 conductive, as well as the switch of C , which locks the R / S rocker in this new state. The device is then brought back to the state where the capacitor charges
In a variant, the amplitude for which the discharge of the capacitor is triggered can be made variable. FIG. 4 represents an integrated circuit device which further comprises a fourth of said modules and two transistors TC and TR mounted in differential pair, the one of the transistors (TC) of this pair having its base connected to the current output of the aforesaid first module A and its collector connected to the current output of said fourth module D however that a switch of this same fourth module is connected to the current output of the above third module C.

The base of the second transistor TR is joined to an output, brought to an adjustable reference potential. As a result, when the potential of the current output terminal of module A drops below this adjustable reference potential, the transistor TC becomes conductive and plays the same role as the zener diode of FIG. 3. The advantage is that the voltage for which the reversal of operation occurs is adjustable. The diode 16 is used to limit the amplitude of the voltage applied to the current output of the module D. The total current in the pair TC-TR is conventionally fixed by a current mirror T6-T7 and a current source T8 , of course consisting of an injector of the type
I2L.

 FIG. 5 finally, represents an arrangement which further comprises a sixth of said modules (F) and a seventh of said modules (G), connected in cascade and inserted in the connection which connects the current output of the aforesaid third module C to a switch of the above fourth module D, and this arrangement also includes an eighth module H, a switch of which is connected to the current output of the sixth module F.

When the switch on module H is conductive, it blocks the switch on module F, thus preventing modules D and G from transmitting any information. The current cycle continues only until the module
He should have acted. If later, a negative pulse at the input of module H blocks its switch, this momentarily opens the chain of DGFC modules and switches
R / S is triggered and causes the start of a cycle. In the meantime, the switch on module H has again become conductive and operation stops again after a charge and discharge cycle of the capacitor. The device therefore constitutes a monostable oscillator.

Claims (9)

- REYENDICATIONS  1.- Integrated circuit device constituting an oscillator in association with at least one capacitor, and comprising at least one module, of the type used in the logic technique known as current injection 1 module associating a transistor (2), which constitutes at least a switch, to a current source provided with a current output (E) while the emitter of said transistor (2) is connected to a point (5) called common point, device characterized in that it associates at least a first of said modules () to a controlled current generator (12) 1 the current output of said first module (A) being connected to one of the terminals of the controlled current generator (12), and also to a connection for connection to said capacitor (10).  2.- Integrated circuit device according to claim 1, characterized in that said common point (5) is connected to a first terminal (V-) supplying the circuit via a resistor (R1).  3.- Integrated circuit device according to one of claims 1 or 2, characterized in that the controlled current generator 12) consists of an assembly comprising a fixed current generator (14) coming from a second terminal d supply of the circuit (V +) t of a control transistor (T3) and of a current mirror (T4, T5), and in that the emitter of the control transistor (T3) is connected to said fixed current generator and that its collector is connected to the input of the current mirror whose output current forms the current of said controlled generator.  4.- Integrated circuit device according to claim 3, characterized in that the base -ditit control transistor (T3) is connected to said common point (5).  5.- Integrated circuit device according to all of claims 2 and 3, characterized in that the base of said control transistor (T3) is connected to a potentiometric tap of said resistor  6.- Integrated circuit device according to any one of claims 2 to 5, characterized in that it combines a second and a third of said modules, the current output of the second module (B) being connected both to a switch of the third module (C) and a switch of said first module (A) while the current output of the third module (C) is connected to a switch of the second module (B) and in that the emitter of said transistor control is also connected to at least one switch of the second module.  7.- Integrated circuit device according to claim 6, characterized in that it further comprises a zener diode (Z), a fourth (D) and a fifth (E) of said modules, and in that a switch of said fourth module (D) is connected to the current output of said third module (C), while a switch of the fifth module (E) is connected to the current output of the fourth module (D), its own current output being connected to a terminal of the zener diode (Z), the other terminal of which is connected to the current output of said first module (A)  8.- Integrated circuit device according to claim 6, characterized in that it further comprises a fourth of said modules (D) and two transistors (TC, TR) mounted in differential pair, one of the transistors (TC) of this pair having its base connected to the current output of the aforesaid first module (A) and its collector connected to the current output of said fourth module (D), while a switch of this same fourth module (D) is connected at the current output of the above third module (C).  9.- Integrated circuit device according to one of claims 7 or 8, characterized in that it further comprises  a sixth (F) and a seventh (G) of said connected modules  cascaded and inserted into the connection that connects the output  of the above third module (C) to the switch of the dusdit  fourth module (D) and in that it still includes a hui  tth module <H) of which a switch is connected to the  exit of the sixth module (F).