Wideband LNA with output match configurability

The invention claimed is: 1 . A low noise amplifier (LNA) comprising: an input terminal and an output terminal; the output terminal being connectable to an output load; a first stage coupled to the input terminal; a second stage coupled between the first stage and the output terminal, the second stage including a transistor and a first inductive element; the first inductive element being coupled to a source terminal of the transistor at a first end and connected to a reference voltage at a second end; the second stage being included in a first signal path, the first signal path connecting an output of the first stage to the output terminal; a first capacitor disposed on a second signal path, the second signal path being different from the first signal path and connecting the output of the first stage to the output terminal; wherein: i) the LNA is configured to receive a signal at the input terminal; ii) in a first state: a) the first path is active, and the second path is inactive; and b) the LNA is configured to generate a first amplified signal across the output terminal and ground, and at the first end of the first inductive element; and iii) in a second state: a) the first path is inactive and the second path is active; and b) the LNA is configured to generate a second amplified signal at the output terminal and at the first end of the inductive element; the second amplified signal experiencing a lower gain level than the first amplified signal. 2 . The LNA of claim 1 , further comprising a switching network, the switching network including: a first switch disposed in the second signal path, the first switch connecting the first capacitor to the output terminal, and a second switch disposed in the first signal path, the second switch connecting the output of the first stage to a gate terminal of the second stage transistor. 3 . The LNA of claim 2 , wherein: in the first state: the first switch is open and the second switch is closed; and in the second state: the first switch is closed and the second switch is open. 4 . The LNA of claim 2 , wherein the switching network further comprises: a third switch disposed in the first signal path, downstream of the first inductive element, the third switch connecting the source terminal of the transistor to the output terminal. 5 . The LNA of claim 4 , wherein: in the first state: the first switch is open; the second and the third switches are closed; in the second state: the first and the third switches are closed; the second switch is open. 6 . The LNA of claim 1 , further comprising a switching network, the switching network including: a first switch disposed in the second signal path, the first switch connecting first capacitor to the output terminal; a second switch disposed in the first signal path, the second switch connecting the output of the first stage to a gate terminal of the transistor, and a third switch disposed in the first signal path, upstream of the first inductive element, the third switch connecting the source terminal of the transistor to the output terminal. 7 . The LNA of claim 6 , wherein: in the first state: the first switch is open; the second and the third switches are closed; in the second state: the first switch is closed; the second and the third switches are open. 8 . The LNA of claim 1 , further comprising a switching network, the switching network including: a first switch disposed in the second signal path, the first switch connecting the first capacitor to the output terminal; a second switch disposed in the first signal path, the second switch connecting the output of the first stage to a gate terminal of the transistors; a third switch disposed in the first signal path, downstream of the first inductive element, the third switch connecting the source terminal of the transistor to the output terminal, and a fourth switch disposed in the first signal path, the fourth switch connecting the source terminal of the transistor to the first end of the first inductive element. 9 . The LNA of claim 8 , wherein: in the first state: the first switch is open; the second, the third and the fourth switches are closed; in the second state: the first and the third switches are closed; the second and the fourth switches are open. 10 . The LNA of claim 2 , where in the first inductive element comprises a first inductor arranged in series with a second inductor, and wherein the first inductor is a variable or a fixed inductor, and the second inductor is a selectively switchable inductor. 11 . The LNA of claim 10 , further comprising a second inductive element coupled to the output of the first stage, and wherein the second inductive element includes a third inductor arranged in series with a fourth inductor, the third inductor being switchable. 12 . The LNA of claim 11 , further comprising an input inductor arranged in series with an input capacitor; a combination of the input inductor and the input capacitor connecting the input terminal to the first stage. 13 . The LNA of claim 3 , further including a third switch disposed on the first signal path downstream from the second switch and coupling the gate terminal of the transistor to ground. 14 . The LNA of claim 13 , wherein the third switch is open in the first state and closed in the second state. 15 . The LNA of claim 1 , wherein the first stage comprises two or more transistors arranged in cascode configuration. 16 . A method of compensating a capacitance of output routes of a low noise amplifier (LNA), the LNA comprising: an input terminal and an output terminal; the output terminal being connectable to an output load; a first stage coupled to the input terminal; a second stage coupled between the first stage and the output terminal, the second stage including a transistor and an inductive element; the first inductive element being coupled to a source terminal of the transistor at a first end and connected to a reference voltage at a second end; and a capacitor; the method comprising: connecting an output of the first stage to the output terminal through the second stage to form a first signal path; connecting the output of the first stage to the output terminal through the capacitor to form a second signal path; receiving an input signal at the input terminal; in a first state: switching out the second signal path; and switching in the first signal path, thereby generating a first amplified signal at the output terminal and across the inductive element; and in a second state; switching out the first signal path; and switching in the second signal path, thereby generating a second amplifier signal at the output terminal and across the inductive element. 17 . The method of claim 16 , wherein the first amplified signal experiences a higher gain than the second amplified signal. 18 . The method of claim 16 , wherein the source terminal of the transistor is connected to the inductive element in the first state and in the second state. 19 . The method of claim 16 , wherein the source terminal of the transistor: is connected to the inductive element in the first state, and is disconnected from the inductive element in the second state. 20 . The method of claim 16 , wherein the inductive element comprises a variable or fixed inductor arranged in series with a switchable inductor.