Amplifier adapted for noise suppression

The invention claimed is: 1. An amplifier adapted for noise suppression, the amplifier comprising: a first input for receiving a first input signal and a second input for receiving a second input signal, the first and second input signals constituting a differential pair; a first output for delivering a first output signal and a second output for delivering a second output signal, the first and second output signals constituting a differential pair; a first transistor having: a first drain coupled to the first output such that all signal current, except parasitic losses, flowing through the first drain flows through the first output; and a first source coupled to the first input; a second transistor having: a second gate coupled to the first input; a second drain coupled to the second output such that all signal current, except parasitic losses, flowing through the second drain flows through the second output; and a second source coupled to a first voltage rail; a third transistor having: a third gate coupled to the second input; a third drain coupled to the first output such that all signal current, except parasitic losses, flowing through the third drain flows through the first output; and a third source coupled to the first voltage rail; a fourth transistor having: a fourth drain coupled to the second output such that all signal current, except parasitic losses, flowing through the fourth drain flows through the second output; and a fourth source coupled to the second input; a first load coupled between the first output and a second voltage rail; a second load coupled between the second output and the second voltage rail; a first inductive element coupled between the first input and a third voltage rail; and a second inductive element coupled between the second input and the third voltage rail; wherein transconductance of the first transistor is substantially equal to transconductance of the fourth transistor within ±5%; and wherein transconductance of the second transistor is substantially equal to transconductance of the third transistor within ±5%; wherein: the transconductance of the second transistor exceeds the transconductance of the first transistor; and the transconductance of the third transistor exceeds the transconductance of the fourth transistor. 2. The amplifier of claim 1 , wherein: first transistor has a first gate coupled to a bias voltage rail; and the fourth transistor has a fourth gate coupled to the bias voltage rail. 3. The amplifier of claim 1 , wherein: first transistor has a first gate coupled to the second input; and the fourth transistor has a fourth gate coupled to the first input. 4. The amplifier of claim 1 , wherein: the transconductance of the first transistor is equal to the transconductance of the fourth transistor; and the transconductance of the second transistor is equal to the transconductance of the third transistor. 5. The amplifier of claim 1 , wherein: the transconductance of the second transistor is less than five times the transconductance of the first transistor; and the transconductance of the third transistor is less than five times the transconductance of the fourth transistor. 6. The amplifier of claim 5 , wherein: the transconductance of the second transistor is twice the transconductance of the first transistor; and the transconductance of the third transistor is twice the transconductance of the fourth transistor. 7. The amplifier of claim 5 , wherein: the transconductance of the second transistor is three times the transconductance of the first transistor; and the transconductance of the third transistor is three times the transconductance of the fourth transistor. 8. The amplifier of claim 1 , wherein the transconductance of the first transistor is 0.02 siemens. 9. A receiving apparatus, comprising: an amplifier; wherein the amplifier comprises: a first input for receiving a first input signal and a second input for receiving a second input signal, the first and second input signals constituting a differential pair; a first output for delivering a first output signal and a second output for delivering a second output signal, the first and second output signals constituting a differential pair; a first transistor having: a first drain coupled to the first output such that all signal current, except parasitic losses, flowing through the first drain flows through the first output; and a first source coupled to the first input; a second transistor having: a second gate coupled to the first input; a second drain coupled to the second output such that all signal current, except parasitic losses, flowing through the second drain flows through the second output; and a second source coupled to a first voltage rail; a third transistor having: a third gate coupled to the second input; a third drain coupled to the first output such that all signal current, except parasitic losses, flowing through the third drain flows through the first output; and a third source coupled to the first voltage rail; a fourth transistor having: a fourth drain coupled to the second output such that all signal current, except parasitic losses, flowing through the fourth drain flows through the second output; and a fourth source coupled to the second input; a first load coupled between the first output and a second voltage rail; a second load coupled between the second output and the second voltage rail; a first inductive element coupled between the first input and a third voltage rail; and a second inductive element coupled between the second input and the third voltage rail; wherein transconductance of the first transistor is substantially equal to transconductance of the fourth transistor within ±5%; and wherein transconductance of the second transistor is substantially equal to transconductance of the third transistor within ±5%; wherein: the transconductance of the second transistor exceeds the transconductance of the first transistor; and the transconductance of the third transistor exceeds the transconductance of the fourth transistor. 10. The receiving apparatus of claim 9 : further comprising a balun and a mixer: wherein the first input and the second input are coupled to a differential output of the balun; and wherein the first output and the second output are coupled to a differential input of the mixer. 11. The receiving apparatus of claim 10 , further comprising an antenna coupled to a single-ended input of the balun. 12. A mobile communication device, comprising a receiving apparatus comprising an amplifier; wherein the amplifier comprises: a first input for receiving a first input signal and a second input for receiving a second input signal, the first and second input signals constituting a differential pair; a first output for delivering a first output signal and a second output for delivering a second output signal, the first and second output signals constituting a differential pair; a first transistor having: a first drain coupled to the first output such that all signal current, except parasitic losses, flowing through the first drain flows through the first output; and a first source coupled to the first input; a second transistor having: a second gate coupled to the first input; a second drain coupled to the second output such that all signal current, except parasitic losses, flowing through the second drain flows through the second output; and a second source coupled to a first voltage rail; a third transistor having: a third gate coupled to the second input; a third drain coupled to the f