Class A amplifier

BradtheRad said:

Generally the high-side resistor can be about the same (up to 150% ohm value) as your load resistor. Tentatively you can than get the output at collector leg to hover around a range midway between your supply rails.

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D.A.(Tony)Stewart said:

Using a -ve supply to create 20 dBm the amplifier needs to deliver a peak voltage swing of 3.16 V and a peak current of 63.2 mA into the 50-ohm load.

- Design for Id = 70 mA
- to maximize fT use the minimum channel length, L = 180nm
- choose a Vt= 2x Vdsat = 0.4V and Vgs-Vt = 0.2V
- thus I estimate W=46 μm should give us the desired current.
- gm = 17.6 mS, Cgs = 47.5 fF,
Use multi-finger gate paths to lower RC using 2.5 μm fingers use 20 fingers, giving W=50 μm and Id = 76 mA min using Vdd = 5V. You may choose a lower Vdd.
- ensure you have thermal vias below chip and wide traces to conduct heat away.

What do you get?

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sze wen said:

How

How does W/L will give you the current needed?
The Cgs is the parasitic capacitance?
What happened to the inductor of 2.5nH?

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D.A.(Tony)Stewart said:

If you studied FETs I should not have to tell you how to compute W/L , Cgs.

2.5 nH could be a 4 or 5mm trace and is 70 Ohms at 4.5 GHz for some reason.

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D.A.(Tony)Stewart said:

The process design kit (PDK) manual for 180 nm ought to tell you that. Have you read it?

I believe in a 180nm CMOS process, μm for NMOS transistors typically ranges from 300 to 500 cm²/V·s

The gate oxide capacitance per unit area Cox=ϵox/tox
ϵox = ϵr⋅ϵ0 , ϵr= 3.9 approx.
tox = is typically around 4 to 4.5 nm thick

so correct me if I am wrong.

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