Oscillator circuit with thermal feedback

Oscillators – Solid state active element oscillator – Significant distributed parameter resonator

Reexamination Certificate

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Details

C331S066000, C331S10800D, C331S176000

Reexamination Certificate

active

06326858

ABSTRACT:

BACKGROUND OF THE INVENTION
Electronic systems commonly utilize electronic signals for processing information or performing specified functions. Electronic signals are time varying voltage or current values that occur at various specified portions of the electronic system. For example, a particular circuit node may experience a particular change in voltage over time. Moreover, such a change in the voltage may take on recurring values over time in a regular manner (i.e. the voltage on the node is periodic). Typically, time varying voltages and currents are compared, added, subtracted. multiplied, or otherwise processed to perform various functions corresponding to the particular type of electronic system. In order to more efficiently carry out such processing, many electronic systems utilize circuits which generate an electronic signal with a constant period. Such circuits are known as oscillator circuits and are found in many types of electronic systems.
Generally, an oscillator circuit is a device for periodically transferring electrical energy between components.
FIG. 1
illustrates a closed loop architecture commonly employed for oscillator circuits. The oscillator circuit of
FIG. 1
is comprised of a feed forward stage and a feedback stage. Amplifiers are commonly used in the feed forward stage to produce the periodic electronic output signal Vo so that the oscillations will continue indefinitely without damping out. The feedback stage receives the periodic electronic output signal Vo and generates a feedback control signal Vf which is either added, subtracted or in some other way combined with the system input signal Vs to control the periodic electronic input signal Vin at the feed forward stage. In order for the closed loop architecture of
FIG. 1
to achieve steady state oscillation, the amplifier A(j&ohgr;) must provide sufficient gain, and the feedback stage F(j&ohgr;) must shift the phase of the output signal a sufficient amount such that the feedback control signal is in phase with the input signal. The mathematical expression of these requirements can be established by following the signal flow around the feedback loop. The gain of the amplifier can be written as
Vo=VinA
(
j
&ohgr;).
The gain around the loop can be established as
Vf=Vo F
(
j
&ohgr;)=
VinA
(
j&ohgr;
)
F
(
j
&ohgr;),
and the transfer function of the system is
Vf/Vin=A
(
j
&ohgr;)
F
(
j
&ohgr;).
Therefore, the magnitude and phase conditions for oscillation can be shown as:
|Vf/Vin|=|A
(
j
&ohgr;)||
F
(
j
&ohgr;)|≧1.0&phgr;
A
+&phgr;
B
=0°
where &phgr;
A
and &phgr;
B
are the phase shifts associated with the amplifier and feedback network respectively.
Oscillator circuits according to the architecture of
FIG. 1
can be implemented in a variety of ways. The underlying characteristic common to each implementation is the idea that electric energy is transferred between various parts of the system during oscillation cycles. For example, some oscillator circuits charge or discharge an inductor or capacitor during the alternate phases of the oscillation cycle. The use of inductors and/or capacitors for storing and discharging energy is an example of an oscillation system which transfers electromagnetic energy between two or more devices capable of storing electromagnetic energy. An example of a well-known oscillation system that utilizes the transformation of electromagnetic energy is the Wien-Bridge Oscillator shown in FIG.
2
. The feedback stage of the Wien-Bridge Oscillator uses a resistor and capacitor network for alternately storing and discharging electromagnetic energy according to principles well-known by those skilled in the art.
Other well known oscillator circuits employ energy storage elements that store mechanical energy during the course of an oscillation cycle. A crystal oscillator is a typical example. In a crystal oscillator, electromagnetic energy is transferred into mechanical energy by applying an electric signal across the crystal structure, thereby causing the crystal lattice to change its physical orientation. Such a change in orientation is achieved by the absorption of electromagnetic energy. For example, in a quartz crystal oscillator, a voltage applied across the crystal will cause the crystal to move sideways internally in a thickness shear movement. Moreover, a quartz crystal can be modeled as a damped LC circuit, and will have a resonant frequency corresponding to the physical properties of the crystal structure. Examples of two oscillator circuits that utilize the mechanical energy storage properties of quartz crystals are shown in FIG.
3
and FIG.
4
. The oscillator circuit of
FIG. 3
utilizes a feed forward stage comprised of a amplifier
301
. The feedback stage utilizes a quartz crystal
302
in a series configuration. In this configuration electrical energy at the resonant frequency of the quartz crystal
302
is transferred into mechanical energy in the crystal structure, and then back into electrical energy at the input of the amplifier.
FIG. 4
, on the other hand, shows a shunt oscillator circuit with feedback stage comprised of a series capacitor
403
and a shunt quartz crystal
402
. The shunt oscillator circuit of
FIG. 4
includes a 90° phase lag network using a shunt impedance
406
and the amplifier's source resistance, illustrated by resistor
405
, to provide the phase lag. The lag network is required to compensate for the 90° phase shift introduced by capacitor
403
to bring the total phase around the loop to 0° as required for oscillation. In both series and shunt configurations of FIG.
3
and
FIG. 4
respectively, the crystal is being used to transfer electromagnetic energy into mechanical energy during alternate phases of the oscillation cycle.
However, electromagnetic and mechanical storage elements share a common problem. In an effort to reduce costs, electronic system designers strive to integrate various components onto a single semiconductor integrated circuit while utilizing a minimal amount of semiconductor area. Unfortunately electromagnetic storage elements such as capacitors and inductors typically occupy large areas of semiconductor area and are, therefore, often provided by external discrete components that occupy large areas on the printed circuit board and correspondingly increasing system costs. Mechanical storage elements also are traditionally provided as external discrete components which also occupy large areas on the printed circuit board and correspondingly increase system costs. Therefore, there is a need to find other solutions for enabling oscillation circuits which can be fully integrated onto a single semiconductor integrated circuit.
SUMMARY OF THE INVENTION
The present invention relates to an oscillation circuit that translates electrical energy into thermal energy in the feedback stage of the circuit to generate a periodic electronic signal at the output of the circuit. The oscillator circuit according to the present invention includes a feed forward stage that receives a periodic electronic input signal on an input node and produces a periodic electronic signal on an output node. The oscillator circuit also includes a feedback stage coupled to the output node to receive the output signal, and in accordance therewith, generate a thermal feedback signal for controlling the input node.
The feedback stage of the present invention includes a thermal element to produce a thermal feedback signal and a thermal sensing element to receive the thermal feedback signal. The thermal signal is produced by the thermal element in response to the periodic electronic output signal. The thermal element translates the energy in the periodic electronic output signal into thermal energy in the form of a thermal signal. This energy translation is achieved according to the Peltier Effect. Peltier heating and cooling at the junctions of dissimilar metals establishes a differential thermal signal that stores electromagnetic energy. The electroma

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