NO814087L - CONTROLLABLE OSCILLATOR - Google Patents

Description

This invention relates to a controllable or steerable

oscillator.

A form of controllable oscillator is the voltage controlled oscillator (V.CO.): (voltage controlled oscillator) which is widely used in phase-locked loops.

A known form of voltage controlled oscillator is the astable multivibrator described in "Electronics", September 11, 1980, pages 124 through 130.

In the astable multivibrator, the oscillator frequency is controlled by the ratio of partial currents in the two halves of the multivibrator circuit.

A problem with this type of known circuit is that it has an operating frequency that is strongly temperature-dependent and it is necessary, in many cases, to use relatively complex, temperature-dependent compensation circuits to achieve the necessary temperature stability of the operating frequency.

This invention aims to create a controllable oscillator which reduces this problem.

According to this invention, there is provided a controllable oscillator, comprising charge-storage device, a comparator for comparing two signals, one of which is dependent on the state of charge of the charge-storage device, and the other is a reference signal. The comparator is connected to control charging and discharging of the charge-storage device, depending on the relative strength of the two signals, to produce an oscillating signal.

The charge-storage device may be a capacitor. The comparator may be arranged to control the current which controls charging and discharging of the charge-storage device.

The comparator may be effective in controlling the current through the respective current sensing circuits to charge and discharge the charge storage device.

The comparator may include a differential amplifier which

. provides an output current from one or other of two outputs, relative to the strength of the two signals.

The differential amplifier may be formed by two current-switching devices arranged to switch a common current to one or other of the two outputs.

The current switch device can be transistors that are fed from a common partial current.

A control device can be provided which controls the common current, thereby controlling the oscillator frequency

on the oscillator..

The two signals can be fed to the respective inputs of the comparator by means of a signal-follower circuit, which can be a transistor, connected as an emitter-follower (emitter follower) circuit.

A device can control the strength of the reference signal, depending on whether the charge-storage device is being charged or discharged.

The device for controlling the strength of the reference signal may further include a comparator, arranged to compare the two signals in parallel with the first-mentioned comparator,

and which has an output to control the strength of the reference-s in the grunt.

The second comparator may contain another differential amplifier to switch current between one of two paths, one of which is connected to control the strength of the reference signal.

Current can be fed via a current-controlled circuit which can be a current mirror (current mirror), to control the strength of the reference signal.

The reference signal can be a reference potential, and can be formed by sending current through a resistor.

The reference potential can be controlled to assume a different value by shorting the resistance.

An example of an embodiment of the invention will now be described with reference to the drawings which illustrate a controllable oscillator in accordance with this invention.

The circuit shown includes a charge-storage device

in the form of a capacitor 1 which is connected between a reference potential 2 and a circuit connection point 3. A transistor Tl, which is connected as an emitter follower, has its base 4 connected to the circuit connection point'3, and an emitter 5 which feeds an input of a comparator circuit.

The comparator circuit consists of transistors T3 and T4, connected as a differential amplifier and having the emitters 6 and 7 connected together, and to an adjustable current source 8. The transistor T3 has its base 9 connected to the emitter 5 of the transistor T1 to form an input of the comparator .

Another input to the comparator is supplied with a reference signal in the form of a reference potential which is derived from a resistor 10 which has one terminal connected to the reference potential 2, and another terminal connected to a connection point 11 which is connected to a current source 12.

Junction point 11 is connected to base 12 of transistor T2 which, like transistor T1, is connected as an emitter follower and has emitter 13 connected to base 14 of transistor T4, to provide a reference potential input to the comparator. .

The transistor T3 has a collector 15 which feeds a current control circuit in the form of a current mirror, which is constituted by the transistors T7 and T8 of opposite conductivity types, to the transistor T3.

The transistors T7 and T8 have collector-current paths 16 and 17 which are connected in parallel with each other, and have the emitters connected to the reference potential 2.

Transistors T7 and T8 have bases 18 and 19 connected together.

Base 18 of transistor T7 is cross-connected to its collector current path 16.

The current flowing in the current path 17 on transistor T8 is controlled by means of another current control circuit, which also has the form of a current mirror, consisting of transistors T9, T10 and Til with the opposite conductivity type compared to transistors T7 and T8.

The current flowing in the collector current path 17 in transistor T8 flows into the collector 20 of transistor T9 which has a common base connection 21 with transistor T10. The transistor has a collector 22 which is connected to the circuit connection point 3, and the emitters of both transistors T9 and 1.0 are connected to a reference potential 23.

The transistor T1 is connected between the common base point 21 and the collector 20 of transistor T9. The base 24 of transistor T1 is connected to the collector 20 of transistor T9, but the emitter 25 of transistor T1 is connected to the common base connection 21.

The transistor T4 feeds a collector current path 26. and current flowing in that path 26 is controlled by means of a current-mirror circuit formed by transistors T12 and T13. both of which have counter-

set conductance type to transistor T4.

The transistor T12 here has a collector 27 connected to collector 26 of transistor T4, and base 28 connected to base 29 of transistor T13. Base and collector 28 and 27, associated transistor T12 are connected together, and collector 30 of transistor T13 is connected to circuit point 3. The emitters of both transistors T12 and T13 are connected to the reference potential 2.

During operation, the transistors T3 and T4 which form the differential amplifier comparator will divide the current fed from the current source 8, bg one of these transistors will be turned off

"on" while the other is turned "off", depending on the relative strength of the potentials at junctions 3 and 11, and these potentials are fed to the comparator through the respective emitter-follower transistors T1 and T2.

Assume that transistor T3 is switched on • so that the current flows in the collector 15 of transistor T3 and through the collector-current path 16 of transistor T7.

The current-mirror circuit formed by transistors T7 and T8 controls the current flowing through transistor T3 and into the collector-current path 17 of transistor T8, and this current is in turn controlled by the current-mirror circuit formed by transistors T9, T10 and Til, through the collector current path 20 of transistor T9 and into the collector current path 22 of transistor T10 up to connection point 3.

Since the transistor T3 is switched on and T4 is switched off, the transistors T12 and T13, which form a current mirror connected to the collector 26 of transistor T4, are also switched off, so that the current flowing in the collector path 22 of transistor T10 enters the connection point 3 will effectively charge capacitor 1 which is also connected. this connection point 3.

While the comparator 1 is charging, current also flows through the resistance .10 which is fed from the current source 12, and the potential at the connection point 11 will therefore be relatively low. The potential at connection point 3, which will be high initially due to transistor T13 being turned off, will decrease linearly as capacitor 1 is charged through transistor T10.

When the potential 3 falls below the value of the potential in connection point 11, the differential amplifier will shift so that the current fed from the current source 8 will flow through the transistor T4 which causes the transistor T2 to be switched on, while the transistors Tl and T3 are switched off. . When the transistors Tl and T3 are switched off, the transistors T7, T8, T9, T10 and Til will also be switched off, so that the capacitor 1 is no longer charged. But the transistors T12 and T13 will at this time be turned on, so that the collector current that follows in the collector 26 of the transistor T4 will be controlled by the current-mirror circuit formed by the transistors T12 and T13, and will flow through the collector 30 on transistor T13. Capacitor 1 will now discharge through transistor T13, and the potential at connection point 3 will begin to rise again.

When the differential amplifier switches so that transistor T3 is turned off and transistor T4 is turned on, the second part of the oscillator circuit to be described now will come into action.

This second part also includes a comparator in the form of a differential amplifier connected in parallel with the comparator formed by the transistors T3 and T4. The differential amplifier has transistors T5 and T6 with coupled emitters fed with a common current from a current source 31. Basis of

, transistor T5, 32, is connected to base 9 of transistor T3, and collector 33 is connected to a reference potential 34.

Likewise, transistor T6 has base .35 connected to base 14 of transistor T4 and feeds collector current across collector-current path 36 and through a current-controlled circuit to junction point 11.

The current control circuit is another current mirror circuit, formed by transistors T14 and T15, and is of the opposite conductivity type to transistor T4, and these transistors are connected as a current mirror circuit in exactly the same way as transistors T7 and T8. Transistor T14 has its collector connected to the collector-current path 36 of transistor T6, while transistor T15 is connected to supply junction 11, and the base and collector of transistor T14 are connected together.

During the period when capacitor 1 was charged from current. that passed through transistor T3 was transistor T5. on the time-liger comparator conducting, but its collector current would not influence the operation of the circuit since collector 33 is connected to the reference potential 34. However, when the comparator switches like this

that transistor T4 conducts, transistor T6 will also begin to conduct current, and its collector current following in the collector current path 36 will be controlled by the current mirror circuit formed by

transistor Tl4 and T15 to the connection point 11, and this will effectively short-circuit the resistor 10 which is connected between the connection point 11 and the reference potential 2. When then the transistors T3 and T4 switch over, the potential at the connection point 11 will therefore rise very quickly.

As already described, during the discharge of capacitor 1, the potential at junction point 3 will rise linearly, and this rise will continue until the potential at junction point 3 rises above the new high value that appears at junction point 11, and this leads to switching in the transistors

T3 and T4. At this point, transistors T3 and T4 will switch over so that transistor T3 becomes conductive, and transistor T4 together with transistors T2, T12, T13; T14 and T15 will. is turned off and the operation will repeat.

The circuit will therefore oscillate and will provide an oscillator signal at connection point 3, which has the waveform of a triangle, and at connection point 11 an oscillator signal that has the form of a rectangular wave.

To control the frequency of the oscillator, one can adjust the current at the current source 8, and as that current provides the charging current for capacitor 1, it will determine the charging time for the capacitor and thus the time it takes the circuit to switch over.

The circuit is temperature stable because it is completely symmetrical. Any error due to temperature in the part of the circuit that charges the transistor is compensated by similar errors in the part where the capacitor discharges and the reference side of the circuit.

The analysis assumes that the base current through the emitter-follower transistors Tl and T2 is negligible, but if that were not the case, then a variation in frequency with temperature could occur due to the temperature dependence of the base current of these transistors. However, this can be relatively easily compensated for by adding an equivalent current increase in the base circuits of these transistors.

The circuit described with reference to the drawing is only an example, and modifications may be made without departing from the scope of this invention. E.g. the charging device has been produced in the form of a capacitor. The

is not necessary. Any suitable charging device can be used.

Claims (13)

1. Controllable oscillator comprising a charge-storage device, a comparator for comparing two signals, one of which is representative of the state of charge of the charge-storage device, and the other a reference signal, the comparator being adapted to control charge and discharging the charge-storage device depending on the relative strength of the two signals to produce an oscillating signal. 2. Oscillator according to claim 1, characterized in that the charge-storage device is a capacitor. 3. Oscillator according to claim 1 or 2, characterized in that the comparator is arranged to control current • for control of charge and discharge of the charge-storage device. 4. Oscillator according to claim 3, characterized in that the comparator effectively controls the current through the respective current-mirror circuits to charge and discharge charge-storage. the device. 5. Oscillator according to one of the preceding claims, characterized in that the comparator includes a differential amplifier which provides an output current from one or the other of two outputs depending on the relative strength of the two signals. 6. Oscillator according to claim 5, characterized by. that the differential amplifier consists of two current switching devices designed to switch a common current to one or other of the two outputs. 7. Oscillator according to claim 6, characterized in that the current switching devices are transistors which are fed with a common current (common tail current). 8. Oscillator according to claim 6 or 7, characterized in that a control is provided to control the strength of the common current in order to control the oscillator frequency of the oscillator. 9. Oscillator according to one of the preceding claims, characterized in that the two signals are fed to respective inputs on the comparator by means of each signal follower circuit. 10.. Oscillator according to one of the preceding claims, characterized by . a device for controlling the strength of the reference signal depending on whether the charge-storage device is being charged or discharged. 11. Oscillator according to claim 10, characterized in that the device for controlling the strength of the reference signal includes another comparator arranged to compare the two signals in parallel with the first-mentioned comparator, and with an output connected to control the strength of the reference signal. 12. Oscillator according to claim 11, characterized in that the second comparator includes another differential. amplifier that switches current between one or the other of two paths, one of which is connected forward. to check the strength of the reference signal. 13. Oscillator according to claim 12, characterized in that current is fed via a current control circuit to control the strength of the reference signal.