Differential amplifiers may be employed in a variety of electronic circuits including circuits that operate at radio frequency (RF), microwave, and millimeter wave frequencies. A differential amplifier may include a pair of transistors that generate a differential output signal at a pair of output ports in response to a differential input signal received at a pair of input ports.
A prior differential amplifier may include a set of individual inductor components. For example, inductor components may be used for transistor biasing in a differential amplifier. In addition, inductor components may be used for impedance matching at the input and/or output ports of a differential amplifier. Inductor components may also be used for noise reduction in a differential amplifier.
Unfortunately, the physical space taken up by the winding structures of individual inductor components may hinder attempts to decrease the physical size of a differential amplifier. The size limitations imposed by the physical dimensions of inductor components may be a particular hindrance in the design of differential amplifiers contained on integrated circuit chips. In addition, electrical interactions that may occur between individual inductor components may alter the frequency response of a differential amplifier away from its desired response.
A differential amplifier is disclosed that employs mutually coupled inductors to provide desired levels of inductance in a substantially smaller form factor in comparison to individual inductor components. Mutually coupled inductors according to the present teachings may also be used to increase common mode rejection in a differential amplifier.
Other features and advantages of the present invention will be apparent from the detailed description that follows.
The present invention is described with respect to particular exemplary embodiments thereof and reference is accordingly made to the drawings in which:
The differential amplifier 10 includes a pair of mutually coupled inductors in the form of a transformer T1. The mutually coupled inductors in the transformer T1 in the embodiment shown are used for biasing the transistors Q1 and Q2 and for providing impedance matching at the output ports PORT OUT PLUS and PORT OUT MINUS of the differential amplifier 10.
The transformer T1 is wired so that the effective inductances of its individual inductor windings are augmented by mutual coupling when the differential amplifier 10 is excited in the differential mode. This augmentation of inductance substantially reduces the physical size of the windings structure of the transformer T1 in comparison to the physical size of the winding structures of separate inductor components as in the prior art that achieve the same values of inductance. Thus, the transformer T1 is substantially smaller than individual inductor components having equivalent inductance both in terms of circuit footprint and the number of the turns. The circuit space/size savings provided by the transformer Ti enables an overall reduction in the physical size of the differential amplifier 10.
In the common mode, the transformer T1 is excited in common mode from the drains of the transistors Q1 and Q2 so that the effective inductances of the windings of the transformer T1 are reduced by the effect of mutual coupling. This reduction in inductance in the common mode works to short out the common mode output of the differential amplifier 10 and improves the common mode rejection of the differential amplifier 10.
The differential amplifier 10 in the embodiment shown includes a pair individual inductor components L1 and L2 that may be used to provide input port matching for the differential amplifier 10. In other embodiments, the inductor components L1 and L2 may be omitted from the circuit.
The transformer T2 is wired so that the effective inductances of its individual inductor windings are augmented by the mutual coupling when the differential amplifier 20 is excited in the differential mode. Thus, the overall size of the transformer T2 can be made substantially smaller than if two separate inductor components were to be used to provide input impedance matching and noise control.
The differential amplifier 20 in the embodiment shown includes a pair of individual inductor components L3 and L4 that may be used for transistor biasing and output port matching in the differential amplifier 20. The inductor components L3 and L4 may be omitted from the circuit. Alternatively, the inductor components L3 and L4 may be replaced with a transformer, such as the transformer T1 in
The differential amplifier 30 in the embodiment shown includes a pair of individual inductor components L5 and L6 that may be used for transistor biasing and output port matching for the differential amplifier 30 or that may be omitted from the circuit. Alternatively, the inductor components L5 and L6 may be replaced with a transformer such as the transformer T1 in
The present techniques enable a reduction in the physical size of a differential amplifier while also improving the common mode rejection of the differential amplifier. The present techniques also improve the layout robustness of a differential amplifier circuit in terms of unwanted parasitic couplings.
The foregoing detailed description of the present invention is provided for the purposes of illustration and is not intended to be exhaustive or to limit the invention to the precise embodiment disclosed. Accordingly, the scope of the present invention is defined by the appended claims.