Introduction to Electronic Circuit

Introduction to Electronic Circuit

Electronic Circuit DesignElectronic Circuit DesignCHO, Yong HeuiCHO, Yong Heui

Electronic Circuits Electronic Circuits DesignDesign

EM Wave LabEM Wave Lab2

1. Diode

Nonlinear device

No voltage drop External circuits

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EM Wave LabEM Wave Lab3

iD = 0, vD ≤ VD0

iD = (vD - VD0) / rD , vD ≥ VD0

Piecewise linear model

1. Diode

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EM Wave LabEM Wave Lab4

Mode EBJ CBJ

Cutoff Reverse Reverse

Active Forward Reverse

Rev. Act. Reverse Forward

Saturation Forward Forward

Device structure

2. BJT

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EM Wave LabEM Wave Lab5

iC = ISeVBE/VT·(1+vCE/VA)

∂iC

∂vCE

ro ≡vBE=constant

-1

I-V characteristics

2. BJT

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EM Wave LabEM Wave Lab6

OP amp 의 어떤 terminal 도 ground에 연결되어 있지 않음 .

3 signal terminals and 2 power terminals (Not displayed)

Differential input voltage, single-ended output voltage

Infinite input impedance ii = 0

Zero output impedance

Zero common-mode gain (v2=v1 vo=0)

Infinite open-loop gain A

Infinite bandwidth : A is constant at any frequencies.

*Differential input voltage, single-ended output voltage

Ideal OP Amp

3. OP amp

Ideal OP amp

Electronic Circuits Electronic Circuits DesignDesign

EM Wave LabEM Wave Lab7

Selection of active device

4. Amplifier

pHEMT amplifier with package

Gain [dB]

Bandwidth [Hz]

Stability: oscillation

Noise figure [dB]: LNA

P1dB [dBm]: PA

Characteristics of active device: bias

Bare chip

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EM Wave LabEM Wave Lab8

Bias design

Assignment of AC and DC path

4. Amplifier

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EM Wave LabEM Wave Lab9

LNA (Low Noise Amplifier)

Noise figure: 2 dB Amplifier gain: 15 dB Return loss: 15 dB Reverse isolation: 20 dB Impedance matching: power and noise

4. Amplifier

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EM Wave LabEM Wave Lab10

SNR: signal to noise ratio Noiseless system: NF = 1 Noisy system: NF > 1 Ground

Noise figure (NF)

4. Amplifier

in

out

out

in

out

in

N

N

S

S

SNR

SNRNF

Electronic Circuits Electronic Circuits DesignDesign

EM Wave LabEM Wave Lab11

Simulation of LNA

PortOUTNum=2

PortINNum=1

CC2C=1.0 pF

CC1C=1.0 pF

LL3

R=L=1.0 nH

LL2

R=L=1.0 nH

TSMC_CM025RF_PMOS_RFPMOS_RF1

finger=16width=10 umlength=0.24 umType=2.5V twin-well

TSMC_CM025RF_NMOSNMOS2

Width=0.30 umLength=0.24 umType=2.5V_nom

LL1

R=L=1.0 nH

RR3R=50 Ohm

RR2R=50 OhmTSMC_CM025RF_NMOS

NMOS1

Width=0.30 umLength=0.24 umType=2.5V_nom

RR1R=50 Ohm

HP ADS (Advanced Design System)

AC and DC path

4. Amplifier

Electronic Circuits Electronic Circuits DesignDesign

EM Wave LabEM Wave Lab12

HPA (High Power Amplifier)

Output power (P1dB), power gain Linearity (OIP3) Efficiency (PAE) Temperature

Power amplifier scheme

4. Amplifier

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EM Wave LabEM Wave Lab13

Characteristics

5. Filter

2 port network: S parameters Pass band and stop band Return loss and insertion loss Ripple and selectivity (skirt) Pole and zero Group delay

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EM Wave LabEM Wave Lab14

Classification

LPF (Low Pass Filter) HPF (High Pass Filter) BPF (Band Pass Filter) BSF (Band Stop Filter): notch filter

Duplexer: 2 BPF Diplexer: LPF and HPF

5. Filter

Electronic Circuits Electronic Circuits DesignDesign

EM Wave LabEM Wave Lab15

Frequency conversion

Mixer VCO: Voltage Controlled Oscillator PLL: Phase Locked Loop TCXO: Temperature Compensated Crystal

Oscillator

6. Mixer

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