ORIGIN OF INVENTION

The invention described herein was made by an employee of the U.S. Government and may be manufactured and used by or for the government of the United States of America for Governmental purposes without the payment of any royalties thereon or therefor.

TECHNICAL FIELD

This invention relates generally to oscillators, and more particularly to a frequency stable, low phase noise sinusoidal oscillator.

BACKGROUND ART

Conventional oscillator circuit configurations consist essentially of Colpitts, Hartley, Pierce, and Miller type configurations, or variations thereof. These configurations are generally unstable due to their inherent noise. The inherent noise, which is comprised of ¹ /f, shot, and thermal noise, causes random instantaneous changes in the quiescent current level of the oscillator. The random, instantaneous changes in quiescent current, in turn, produce instantaneous changes in the frequency generated. This effect is called phase noise, and it is generally defined as narrow band phase modulation by noise.

The usual approach to achieving oscillator stability is to utilize high-Q crystals in conjunction with active elements selected for their low noise characteristics. This approach, however, does nothing to reduce oscillator instability caused by inherent noise.

SUMMARY OF THE INVENTION

Accordingly, it is an object of this invention to provide a high frequency sinusoidal oscillator.

Another object of the invention is to provide a frequency stable oscillator.

According to the present invention, the foregoing and other objects are attained by providing a pair of amplifier circuits. The first amplifier circuit has an inductive load impedance and a capacitive input susceptance. The second amplifier circuit has a capacitive load impedance and an inductive input susceptance. The two amplifier circuits can be made to oscillate by making the total closed loop conductance negative and the total closed loop susceptance zero. These conditions are met by connecting the two amplifier circuits in parallel. When this is done, the inductive input susceptance of the second amplifier circuit provides the first amplifier circuit with negative conductance which renders the first amplifier circuit operational as a Hartley oscillator, and the capacitive input susceptance of the first amplifier circuit provides the second amplifier circuit with negative conductance which renders the second amplifier circuit operational as a Colpitts oscillator. The frequency generated by each of the oscillators is identical.

The inherent noise present in both amplifier circuits causes the quiescent current of, and in turn, the frequency generated by, each amplifier circuit to change. The changes in quiescent current cause direct changes in the transconductance and the load impedance of each amplifier circuit. This in turn causes direct changes in the capacitive input susceptance of the first amplifier circuit and the inductance input susceptance of the second amplifier circuit. However, the changes in input susceptance oppose each other in the parallel connected amplifier circuits because the total susceptance is zero. Accordingly, an increase in the quiescent current in one-half of the circuit with an accompanying change in the frequency generated is opposed by a decrease in the quiescent current in the other half of the circuit and an accompanying opposite change in the frequency generated. The changes in frequency cancel, and the net result is a reduction in frequency instability due to inherent noise.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be better understood from the following description which makes reference to the appended drawings wherein:

FIG. 1 is a schematic representation of one amplifier circuit used in this invention.

FIG. 2 is a schematic representation of another amplifier circuit used in this invention.

FIG. 3 is a schematic representation of the amplifier circuits of FIGS. 1 and 2 connected in parallel.

FIG. 4 is a schematic representation of one embodiment of this invention.

FIG. 5 is a schematic representation of another embodiment of this invention.

DETAILED DESCRIPTION

Referring now to the drawings wherein like reference numerals and characters designate identical or corresponding parts throughout the several views, and more particularly to FIG. 1 wherein an amplifier circuit 10 is illustrated. The amplifier circuit 10 includes an amplifier 12 having an input terminal 14, an output terminal 16, and a transconductance g_m1. A capacitor C₁, which provides the amplifier circuit 10 with capacitive input susceptance, shunts the terminals 14 and 16. An inductance L₁ and a resistor R₁ are serially connected between the output terminal 16 and ground. The inductor L₁ provides the amplifier circuit 10 with inductive load impedance.

FIG. 2 illustrates another amplifier circuit 20 having an amplifier 22 with a transductance g_m2, an input terminal 24, and an output terminal 26. The input and output terminals are shunted by an inductor L₂, which provides this amplifier circuit with inductive input susceptance. A capacitor C₂ and a resistor R₂ are connected in series between the output terminal 26 and ground. The capacitor C₂ provides the amplifier circuit 20 with capacitive load impedance.

The two amplifier circuits can be used to model grounded emitter transistor amplifiers. When this is done, the input impedance Y₁ of the amplifier circuit 10, which is a function of angular frequency w, may be expressed as: ##EQU1## and the input impedance Y₂ of the amplifier circuit 20, which is also a function of angular frequency w, may be expressed as: ##EQU2## The values of R₁ and R₂, when compared to the values of the terms jwL₁ +1/jwC₁ and jwL₂ 1/jwC₂ from the denominators of equations (1) and (2), are generally very small in practical transistor circuits. Accordingly, equations (1) and (2) may be expressed as truncated binomial expansions: ##EQU3## When the real and reactive terms are grouped together, equations (3) and (4) reduce to: ##EQU4##

The first term of equation (5) represents the capacitive input susceptance of amplifier circuit 10, while the third term represents the positive feedback, or equivalently, the negative conductance. Correspondingly, the first term of equation (6) represents the inductive input susceptance of amplifier circuit 20, while its third term represents the negative conductance. For the third term of equation (5) to be negative, w² must be less than 1/L₁ C₁, and for the third term of equation (6) to be negative, w² must be greater than 1/L₂ C₂. These conditions imply that an inductance placed across the input terminal 14 of amplifier circuit 10 will guarantee that its closed loop conductance is negative, and that the closed loop conductance of amplifier circuit 20 will be guaranteed to be negative if a capacitance is placed across its input terminal 24.

If the two amplifier circuits are connected in parallel as illustrated in FIG. 3, by interconnecting their input terminals the capacitive input susceptance of the amplifier circuit 10 will provide the amplifier circuit 20 with negative conductance, the inductive input susceptance of the amplifier circuit 20 will provide the amplifier circuit 10 with negative conductance, and the total closed loop conductance will be negative. This circuit configuration effectively renders the amplifier circuit 10 operational as a Hartley-type oscillator and the amplifier circuit 20 operational as a Colpitts-type oscillator. The frequency generated by each of the oscillators in this circuit configuration will be identical because each amplifier circuit provides the other with the conditions necessary for oscillation. Oscillation will be sustained if the total closed loop susceptance is zero, which may be expressed as: ##EQU5## This expression may be simplified by insuring that g_m1 R₁ =g_m2 R₂, which yields: ##EQU6## Solving for w yields: ##EQU7##

FIG. 4 shows a preferred grounded emitter configuration 40 of the oscillator according to this invention. In this embodiment of the circuit includes two matched npn transistors T₁ and T₂ having commonly directly connected base and emitter electrodes. The quiescent operating point of the transistors is set by a voltage divider network connected between a source of B+ voltage and ground, a resistor R_c1 connected between the source of B+ voltage and the collector electrode of the transistor T₁, a resistor R_c2 connected between the source of B+ voltage and the collector electrode of the transistor T₂, and a resistor R_E connected between the common emitter electrodes and ground. The voltage divider network has serially connected resistors R_B1 and R_B2 connected at their juncture 42 to the commonly joined base electrodes of the transistors thereby providing the bases with an intermediate voltage. A capacitor C_B is connected between an adjustable tap on the resistor R_B2 and ground, and a capacitor C_E is connected in parallel with resistor R_E. These capacitors are provided so that resistors R_B2 and R_E only affect the direct current operation of the circuit. The resistor R_B2 is tapped to provide positive admittance across point 42 thereby reducing the excess gain present in the circuit 40, and to limit the severity of any clipping of the sinusoidal oscillations produced by the oscillator circuit 40.

A series network composed of a variable resistor R₁, an inductor L₁, and a capacitor C_c1 is connected between the source of B+ voltage and the collector electrode of the transistor T₁. A series network including a variable resistor R₂ and a capacitor C₂ is connected between the source of B+ voltage and the collector electrode of the transistor T₂. Resistors R₁ and R₂ are variable to allow the terms g_m1 R₂ and g_m2 R₂ from equations (5) and (6) to be varied so that the symmetry of the oscillator circuit 40 can be adjusted. The collector and base electrodes of the transistor T₁ are shunted by a capacitor C₁, and the collector and base electrodes of the transistor T₂ are shunted by the series combination of an inductor L₂ and a coupling capacitor C_c2.

An oscillator frequency of 10 MHz was obtained when the following exemplary components were used in oscillator circuit 40:

T₁ =2N2369

T₂ =2N2369

R_B1 =100 kΩ

R_B2 =33 kΩ

R_C1 =5.1 kΩ

R_C2 =5.1 kΩ

R_E =2 kΩ

C_B =6.1 μf

C_E =0.1 μf

C_c1 =0.1 μf

C_c2 =0.1 μf

R₁ =100Ω

R₂ =100Ω

C₁ =15.9 pf

C₂ =212.0 pf

L₁ =4.0 μH

L₂ =4.8 μH

B+=15 volts

With the proper selection of component values, a stable oscillator can be achieved for any discrete frequency within the range of frequencies of 5 to 20 MHz.

The oscillator circuit 40 is extremely stable. This is in part due to the effect of the inherent noise present in the oscillator circuit 40 which causes the values of the capacitive and inductive input susceptances due to the capacitor C₁ and the inductor L₂ to vary. These variations cause the frequency generated in one half of the circuit to increase and the frequency generated in the other half of the circuit to decrease. The changes in generated frequency oppose each other due to the opposition to each other of changes in input susceptance thereby enhancing the frequency stability.

The oscillator circuit 40 also partially owes its stability to the way the circuit is biased. The resistors R_B1 and R_B2 are chosen so that the bias voltage at the commonly connected bases is equal to one half of the voltage of the source of B+ voltage thereby to assure symmetry of the oscillator signal. The biasing arrangement, along with the symmetrical configuration of the circuit and the tap on resistor R_B2, causes the gain of the circuit to be below the level at which hard limiting or clipping of the oscillator signal occurs. If hard limiting or clipping occurs, excessive noise is produced, which, in turn, produces frequency instability.

To improve the stability of the oscillator circuit 40, a crystal 44 may be inserted in the circuit to replace either of the inductors L₁ or L₂. If the inductor L₂ is replaced with the crystal 44, the oscillator circuit 40 becomes the equivalent of a compensated Pierce oscillator.

The preferred output point of the oscillator circuit 40 is the juncture 42. To take the output signal from this point ensures that the symmetry of the circuit will be maintained. This is because neither half of the circuit will be loaded more than the other half of the circuit.

The two amplifier circuits in FIGS. 1 and 2 may also be used to model grounded base transistor amplifiers. When this is done, the input impedance Y₁ of amplifier circuit 10, which is a function of angular frequency w, can be expressed as: ##EQU8## and the input impedance Y₂ of amplifier circuit 20, which is also a function of angular frequency w, can be expressed as: ##EQU9## The values of R₁ and R₂, when compared to the values of the terms, jwL₁ +1/jwC₁ and jwL₂ +1/jwC₂ from the denominator of equations (10) and (11), are generally very small in practical transistor circuits. Accordingly, equations (10) and (11) may be expressed as truncated binomial expansions: ##EQU10## When the real and reactive terms are grouped together, equations (12) and (13) reduce to: ##EQU11##

The first term of equation (14) represents the capacitive input susceptance of the amplifier circuit 10, and the third term represents the positive feedback, or equivalently, the negative conductance. Correspondingly, the first term of equation (15) represents the inductive input susceptance of the amplifier circuit 20, while its third term represents the negative conductance. When the two amplifier circuits are connected in parallel as illustrated in FIG. 3 by connecting their input terminals to each other, the capacitance input susceptance of amplifier circuit 10 will provide amplifier circuit 20 with negative conductance, the inductive input susceptance of amplifier circuit 20 will provide amplifier circuit 10 with negative conductance, and the total closed loop conductance will be negative. This circuit configuration effectively renders the amplifier circuit 10 operational as a Hartley-type oscillator and the amplifier circuit 20 operational as a Colpitts-type oscillator.

The frequency generated by each of the oscillators in the circuit of FIG. 3 will be identical. This is because each amplifier circuit provides the other amplifier circuit with the conditions necessary for oscillation. Oscillation will be sustained if the total closed loop susceptance is zero, which may be expressed as: ##EQU12## This expression can be simplified by setting g_m1 R₁ equal to g_m1 R₂, which yields: ##EQU13## Solving for w yields: ##EQU14##

Referring now to FIG. 5, a preferred grounded base configuration 50 of the oscillator according to this invention is illustrated. In this embodiment, the circuit includes two matched npn transistors T₁ and T₂ having commonly directly connected base and emitter electrodes. The quiescent operating point of the transistors is set by a voltage divider network connected between a source of B+ voltage and ground, a voltage divider network connected between the common emitter electrodes and ground, a resistor R_C1 connected between the source of B+ voltage and the collector electrode of the transistor T₁, and a resistor R_C2 connected between the source of B+ voltage and the collector electrode of the transistor T₂. The first voltage divider network includes serially connected resistors R_B1 and R_B2 connected at their juncture 52 to the common base electrodes, and the second voltage divider network includes a variable resistor R₃ and a resistor R_E connected in series at point 54. The resistor R₃ is variable to add positive admittance to the juncture 54 to compensate for excess gain present in the circuit 50, and to limit the severity of any clipping of the sinusoidal oscillations produced by this circuit. A bypass capacitor C_B is connected in parallel with the resistor R_B2 to ensure that the resistor R_B2 only affects the direct current operation of the circuit.

A series network composed of a variable resistor R₁, an inductor L₁, and a coupling capacitor C_C1, is connected in parallel with the resistor R_C1, and another series network having a variable resistor R₂ and a capacitor C₂ as connected in parallel with the resistor R_C2. A capacitor C₁ is connected between the collector electrode of the transistor T₁ and juncture 54. An inductor L₂ and a coupling capacitor C_C2 are connected in series between the collector electrode of the transistor T₂ and the point 54.

An oscillator frequency of 10 MHz resulted when the following exemplary components were used in circuit 50:

T₁ =2N2369

T₂ =2N2369

R_B1 =100 kΩ

R_B2 =33 kΩ

R_C1 =5.1 kΩ

R_C2 =5.1 kΩ

R₃ =100 kΩ

R_E =2 kΩ

C_B =0.1 μf

C_C1 =0.1 μf

C_C2 =0.1 μf

R₁ =100Ω

R₂ =100Ω

L₁ =4.0 μH

L₂ =4.8 μH

C₁ =15.9 pf

C₂ =212.0 pf

B+=15 volts

With the proper selection of component values, a stable oscillator can be achieved for any discrete frequency within the range of frequencies of 5 to 20 MHz.

Oscillator circuit 50 is extremely stable. One factor responsible for the stability of the circuit 50 is that the inherent noise present in the circuit causes changes in frequency in either half of the circuit to oppose each other. Another stability enhancing factor is the circuit's biasing arrangement. Additional stabilization may be had by inserting crystal 56 in the circuit to either be in parallel with the resistor R_B2, or in series with the variable resistor R₃.

The preferred output point of the oscillator circuit 50 is the juncture 52. This point ensures that the symmetry of the circuit is maintained because neither half is loaded more than the other half.

Obviously, numerous modifications and variations of the present invention are possible in the light of this disclosure. One such modification of the present invention is that any three terminal active device can be used in the present invention. It is therefore to be understood that within the scope of the appended claims the invention may be practiced other than as specifically described therein.