Introduction 0/4

• Lecture1.1
  RAHRF201 Before We Start
• Lecture1.2
  logo 01 min
• Lecture1.3
  2.1.1. Introduction 01 min
• Lecture1.4
  2.1.2. Introduction 01 min
• Lecture1.5
  RAHRF201 Promotional Video 03 min
• Lecture1.6
  What is Rahsoft RF Certificate? 02 min

Power 0/23

In this section we are going to discuss power in electronic and RF circuits. Initially, basic and yet significant power concepts such as Instantaneous and average power are discussed in details using formula and examples. In the next step complex power and maximum power transform is discussed. Achieving maximum power transfer with matching is one of the most important concepts that one should know first of all in RF design. You are going to learn what is the purpose of using matching circuit in RF design. We talked about this concepts using formula, numerous examples and simulations. As the last part, we explain dB and dBm.

• Lecture2.1
  2.2.1 Instantaneous and average power 06 min
• Lecture2.2
  2.2.2. Power Example 06 min
• Quiz2.1
  Quiz : Q1 1 question
• Quiz2.2
  Quiz : Q2 1 question
• Lecture2.3
  2.2.3.1 Power and Phasor 15 min
• Lecture2.4
  2.2.4. Power and Phasor Example 09 min
• Quiz2.3
  Quiz :Q3 1 question
• Quiz2.4
  Quiz : Q4 1 question
• Lecture2.5
  2.2.5. Complex Power 10 min
• Lecture2.6
  2.2.6. Complex Power Summary 02 min
• Lecture2.7
  2.2.7. Complex Power Example 04 min
• Quiz2.5
  Quiz : Q5 1 question
• Quiz2.6
  Quiz : Q6 1 question
• Lecture2.8
  2.2.8. Complex Power ADS simulation 01 min
• Lecture2.9
  2.2.9. Maximum power 11 min
• Quiz2.7
  Quiz : Q7 1 question
• Quiz2.8
  Quiz : Q8 1 question
• Lecture2.10
  2.2.10 Max power ADS simulation 06 min
• Lecture2.11
  2.2.11. Power and Matching 12 min
• Quiz2.9
  Quiz : Q9 1 question
• Lecture2.12
  2.2.12. Max Power and Matching Summary 03 min
• Lecture2.13
  2.2.13. dB, dBm and power gain 16 min
• Quiz2.10
  Quiz : Q10 1 question

Mos Transistor 0/10

Sensitivity and Dynamic Range are two important factors that we have to know when we are designing a receiver. These two parameters are explained in this section using formula and figures. At the end of this section you will understand the whole concept and you will be able to calculate Sensitivity and Dynamic Range for a given system.

• Lecture3.1
  2.3.1.1 MOS Transistor structure and DC characteristics 16 min
• Quiz3.1
  Quiz : Q11 1 question
• Lecture3.2
  2.3.2 Small Signal 11 min
• Quiz3.2
  Quiz : Q12 1 question
• Lecture3.3
  2.3.3 Small Signal Model 07 min
• Quiz3.3
  Quiz : Q13 1 question
• Lecture3.4
  2.3.4. Parasitic Capacitances 12 min
• Quiz3.4
  Quiz : Q14 1 question
• Quiz3.5
  Quiz : Q15 1 question
• Lecture3.5
  2.3.5 ADS FT 04 min
• Lecture3.6
  2.3.6. MOS Example 1 09 min

Non Linearity 0/19

• Lecture4.1
  2.4.1. Linearity Intro 09 min
• Lecture4.2
  2.4.2. Harmonic Distortion 10 min
• Quiz4.1
  Quiz : Q16 1 question
• Lecture4.3
  2.4.3. Gain Compression 13 min
• Quiz4.2
  Quiz : Q17 1 question
• Lecture4.4
  2.4.4. Gain Compression example in ADS 08 min
• Lecture4.5
  2.4.5. Harmonic Distortion and Gain Compression Summary 03 min
• Lecture4.6
  2.4.6. Desensitization 16 min
• Lecture4.7
  2.4.7. Desensitization Example 07 min
• Quiz4.3
  Quiz : Q18 1 question
• Lecture4.8
  2.4.8. Intermodulation 30 min
• Quiz4.4
  Quiz : Q19 1 question
• Lecture4.9
  2.4.9. Intermodulation IIP3 30 min
• Quiz4.5
  Quiz : Q20 1 question
• Lecture4.10
  2.4.10. Intermodulation Example 1 30 min
• Lecture4.11
  2.4.11. Intermodulation Example 2 17 min
• Lecture4.12
  2.4.12.1 Intermodulation Example 3 06 min
• Lecture4.13
  2.4.13. Cascaded Nonlinear Stages 11 min
• Quiz4.6
  Quiz : Q21 1 question

Noise 0/23

• Lecture5.1
  2.5.1. Introduction To Noise and Power Spectral Density , PSD 08 min
• Quiz5.1
  Quiz : Q22 1 question
• Lecture5.2
  2.5.2. Different Types of Noise. Device Noise, Resistor Noise, MOS Transistor Noise, Thermal Noise, Flicker Noise 13 min
• Quiz5.2
  Quiz : Q23 1 question
• Quiz5.3
  Quiz : Q24 1 question
• Quiz5.4
  Quiz : Q25 1 question
• Quiz5.5
  Quiz : Q26 1 question
• Lecture5.3
  2.5.3 Noise in Circuits , Input Referred Noise 08 min
• Quiz5.6
  Quiz : Q27 1 question
• Lecture5.4
  2.5.4. Input Referred Noise Example 11 min
• Lecture5.5
  2.5.5. Noise Figure, Signal To Noise Ratio , NF part 1 12 min
• Lecture5.6
  2.5.6. Noise Figure, NF part 2 16 min
• Lecture5.7
  2.5.7. Noise Figure for Circuit Example, NF Example 1 10 min
• Lecture5.8
  2.5.8. Noise Figure for Transistor Level Circuit Example, NF Example 2 14 min
• Lecture5.9
  2.5.9. Noise in Cascaded Stages 08 min
• Lecture5.10
  2.5.10. Noise in Cascaded Stages Example, Cascaded NF Example 09 min
• Lecture5.11
  2.5.11. Noise in Passive Reciprocal Circuits 11 min
• Lecture5.12
  2.5.12. Noise in Passive Reciprocal Circuits Example, NF in Passive Reciprocal Circuits Example 02 min
• Lecture5.13
  2.5.13.0 Receiver chain noise power 15 min
• Lecture5.14
  2.5.14.0 Cascaded Stages Example 06 min
• Lecture5.15
  2.5.15.0 Receiver Noise Floor 13 min
• Lecture5.16
  2.5.16.0 More Examples – part 1 23 min
• Lecture5.17
  2.5.17.0 More Examples – part 2 18 min

Sensitivity and Dynamic Range 0/4

• Lecture6.1
  2.6.1. Sensitivity in Radio Frequency 12 min
• Lecture6.2
  2.6.2.1 Sesitivity Example 03 min
• Lecture6.3
  2.6.3. Dynamic Range 12 min
• Lecture6.4
  2.6.4. Dynamic Range Example 02 min

RLC Circuit 0/6

• Lecture7.1
  2.7.1. Passive Components RLC, RLC Resonance Circuit 12 min
• Lecture7.2
  2.7.2. Transfer Function Bandwidth and Quality Factor in RLC Circuits 13 min
• Lecture7.3
  2.7.3. ADS RLC Circuit Simulation Example 02 min
• Lecture7.4
  2.7.4. Quality Factor, Series to Parallel Conversion with Example 12 min
• Lecture7.5
  2.7.5. Quality Factor Example Method 2 08 min
• Lecture7.6
  2.7.6. RLC Matching Circuit 08 min