Miscellaneous active electrical nonlinear devices – circuits – and – Specific identifiable device – circuit – or system – Unwanted signal suppression
Reexamination Certificate
1999-12-21
2001-03-06
Le, Dinh T. (Department: 2816)
Miscellaneous active electrical nonlinear devices, circuits, and
Specific identifiable device, circuit, or system
Unwanted signal suppression
C327S558000, C327S336000, C333S167000
Reexamination Certificate
active
06198345
ABSTRACT:
FIELD OF INVENTION
The invention is directed towards signal filtering with a polyphase filter, in particular, to provide error reduction in quadrature polyphase filters with low open loop gain operational amplifiers.
BACKGROUND
Many radio, video and data communication systems need to distinguish between a desired signal and an image signal and to attenuate the image signal relative to the desired signal. A polyphase filter performs this function.
For example, a heterodyne receiver with a desired signal of 110 MHz and a local oscillator frequency of 100 MHz generates a desired 10 MHz signal, which is easier to demodulate than the 110 MHz signal that requires difficult to build higher frequency components. However, an image signal of 90 MHz is also converted to an image 10 MHz signal that is not removed from the desired 10 MHz signal by conventional bandpass filters. A quadrature polyphase filter has an asymmetric frequency response resulting from the quadrature phase of its two input signals. It passes or attenuates a signal of the same frequency depending on the phase lag or lead between its two inputs. For instance, a quadrature polyphase filter, with a first and second input current, when driven by a quadrature mixer, will pass the desired signal with the second input current leading the first input current and attenuate the image signal with the second input current lagging the first input current.
The polyphase filter has a resonance frequency, at which its response is maximum. One implementation of a quadrature polyphase filter has two damped integrators matched in values and properties, each with an operational amplifier. An ideal polyphase filter has operational amplifiers of sufficiently high open loop gain so that their input voltages are negligibly small compared to their output voltages. As long as the input voltages remain negligibly small, the resonance frequency and the response of an ideal polyphase filter are independent of the input voltages and thus of the open loop gain of the operational amplifiers.
When multiple polyphase filters are used in communication circuits on a single integrated circuit (IC), the open loop gain of the operational amplifiers is limited by the IC's ability to dissipate power. And since the open loop gain of the operational amplifiers varies with IC process parameters and temperature, the polyphase filter's performance will also be dependent on IC process parameters and temperature. Thus, an undesirable result of the low open loop gain of the operational amplifiers of the polyphase filter is that the resonance frequency and response become dependent on IC process parameters and temperature.
SUMMARY
The invention is a circuit to provide error correction to polyphase filters with low open loop gain operational amplifiers. The polyphase filter includes a first and second damped integrator, a first and second cross coupling transconductor, and an inverter. The first transconductor is connected between the output of the second damped integrator and the input of the first damped integrator. The inverter is connected to the output of the first damped integrator and has an inverted output. The second transconductor is connected between the inverted output and the input of the second damped integrator. Each damped integrator includes an operational amplifier, a capacitor, and a feedback transconductor. Both the capacitor and the feedback transconductor connect between the inverting input and the output of the operational amplifier. The polyphase filter has a resonance frequency. The embodiments of this invention include error correction circuits for the polyphase filter: voltage based and current based.
The voltage based error correction circuit provides a correction voltage in series with each capacitor of the polyphase filter. Each correction voltage has a magnitude approximately equal to the magnitude of the input voltage of the corresponding damped integrator and a phase approximately equal to the phase of the input voltage of the corresponding damped integrator. The response of each damped integrator is corrected by subtracting the correction voltage from the capacitor voltage.
The current based error correction circuit provides a correction current to the input of each damped integrator of the polyphase filter. Each correction current has a magnitude proportional to the product of the magnitude of the input voltage, the frequency and the capacitance of the capacitor of the corresponding damped integrator and a phase leading the phase of the input voltage of the corresponding damped integrator by approximately 90°.
The correction voltages and currents reduce the dependency of the performance of the polyphase filter on the open loop gain of its operational amplifiers. Thus, the error correction reduces the dependency of the polyphase filter resonance frequency and response on the IC process parameters and temperature.
REFERENCES:
patent: 4914408 (1990-04-01), Voorman
patent: 5764171 (1998-06-01), Stikvoort
Agilent Technologie,s Inc.
Camras Mike
Le Dinh T.
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