Model No.: MPCT-17205

Curriculum Outline:
1. Design and implementation of switches and attenuators.
2. Design and implementation of Wilkinson power dividers, branch line couplers and Lange couplers.
3. Design and implementation of LPF, BSF,and BPF filters.
4. Design and implementation of filters with PBG structure.
5. Design and implementation of filters with DGS structure.

Features:
1. Training for wireless communication technicians and engineers.
2. To understand the applications and measurements of communication instruments and products.
3. Design and implementation ability training for microwave module circuit.
4. To understand the applications of microstrip line in microwave circuits design.
5. To shorten the gap between academic and industrial circles.

Specifications:
Module 1: MPCT-17205-01
Chapter 1: Design and Implementation of Switch
Experiment 1: Single Pole SPDT Switching (Operation Frequency: 2400 MHz;
Return Loss: > 10 dB; Insertion Loss: < 3 dB; Isolation: > 10 dB)
Experiment 2: Double Pole SPDT Switching (Operation Frequency: 2400 MHz;
Return Loss: > 10 dB; Insertion Loss: < 3 dB; Isolation: > 10 dB)
Experiment 3: Double Pole High Isolation SPDT Switching
(Operation Frequency: 2400 MHz; Return Loss: > 10 dB; Loss: < 3 dB; Isolation: > 20 dB)

Chapter 2: Design and Implementation of Attenuator
Experiment 1: π-type Attenuator (Operation Frequency: 2400 MHz;
Return Loss: > 15 dB; Attenuation: > 20 ± 3 dB)
Experiment 2: T-type Attenuator (Operation Frequency: 2400 MHz;
Return Loss: > 15 dB; Attenuation: > 20 ± 3 dB)
Experiment 3: Voltage-controlled π-type Attenuator (Operation Frequency: 2400 MHz;
Return Loss: > 10 dB; Attenuation: > 30 ~ 10 ± 3 dB)

Module 2: MPCT-17205-02
Chapter 3: Design and Implementation of Wilkinson Power Divider
Experiment 1: Single Stage Wilkinson Power Divider
(Operation Frequency: 2400 MHz; Return Loss: > 25 ± 5 dB;
Coupling: < -3 ± 0.5 dB; Isolation: > 25 ± 5 dB;
Phase difference: 0 ± 5 deg.)
Experiment 2: SIR Wilkinson Power Divider (Operation Frequency: 2400 MHz;
Return Loss: > 20 ± 5 dB; Coupling: < -3 ± 0.5 dB;
Isolation: > 15 ± 5 dB; Phase difference: 0 ± 5 deg.)
Experiment 3: Two Stages Wilkinson Power Divider
(Operation Frequency: 2400 MHz; Return Loss: > 20 ± 5 dB;
Coupling: < -3 ± 0.5 dB; Isolation: > 25 ± 5 dB; Phase difference: 0 ± 5 deg.)
Experiment 4: Unequal Power Wilkinson Power Divider
(Operation Frequency: 2400 MHz; Return Loss: > 15 ± 5 dB;
Coupling: < -2 ± 0.5 dB; Isolation: > 20 ± 5 dB; Phase difference: 0 ± 5 deg.)

Module 3: MPCT-17205-03
Chapter 4: Design and Implementation of Branch line Coupler
Experiment 1: One Single Stage Branch Line Coupler
(Operation Frequency: 2400 MHz;
Return Loss: > 30 ± 5 dB; Coupling: < -3 ± 0.5 dB;
Isolation: > 25 ± 5 dB; Phase difference: -270 ± 10 deg.)
Experiment 2: Size Reduced Branch Line Coupler
(Operation Frequency: 2400 MHz; Return Loss: > 30 ± 5 dB;
Coupling: < -3 ± 1 dB; Isolation: > 25 ± 5 dB;
Phase difference: 75 ± 10 deg.
Experiment 3: Branch Line Coupler with Second Harmonic Suppression
(Operation Frequency: 2400 MHz; Return Loss: > 20 ± 5 dB;
Coupling: < -3 ± 1 dB; Isolation: > 35 ± 5 dB;
Phase difference: -270 ± 10 deg.)
Experiment 4: Two Stages Branch Line Coupler (Operation Frequency: 2400 MHz;
Return Loss: > 20 ± 5 dB; Coupling: < -3 ± 0.5 dB;
Isolation: > 25 ± 5 dB; Phase difference: 90 ± 10 deg.)

Module 4: MPCT-17205-04
Chapter 5: Design and Implementation of Lange Coupler
Experiment 1: Unfolded Lange Coupler (Operation Frequency: 2400 MHz;
Return Loss: > 15 ± 5 dB; Coupling: < -6 ± 0.5 dB;
Isolation: > 30 ± 5 dB; Phase difference: -90 ± 10 deg.)
Experiment 2: Single Stage Lange Coupler (Operation Frequency: 2400 MHz;
Return Loss: > 35 ± 5 dB; Coupling: < -6 ± 0.5 dB;
Isolation: > 30 ± 5 dB; Phase difference: -90 ± 10 deg.)
Experiment 3: Two Stages Lange Coupler (Operation Frequency: 2400 MHz;
Return Loss: > 20 ± 5 dB; Coupling: < -3 ± 0.5 dB;
Isolation: > 25 ± 5 dB; Phase difference: -90 ± 10 deg.)
Experiment 4: Triple Coupled Lines Lange Coupler
(Operation Frequency: 2400 MHz; Return Loss: > 20 ± 5 dB;
Coupling: < -3 ± 0.5 dB;
Isolation: > 30 ± 5 dB; Phase difference: -90 ± 10 deg.)

Module 5: MPCT-17205-05
Chapter 6: Design and Implementation of Ring Coupler
Experiment 1: 180 deg. Ring Coupler (Operation Frequency: 2400 MHz;
Return Loss: > 25 ± 5 dB; Coupling: < -3 ± 0.5 dB;
Isolation: > 35 ± 5 dB; Phase difference: 0 ± 10 deg. / -180 ± 10 deg.)
Experiment 2: Wideband Ring Coupler (Operation Frequency: 2400 MHz;
Return Loss: > 25 ± 5 dB; Coupling: < -3 ± 0.5 dB;
Isolation: > 20 ± 5 dB; Phase difference: -10 ± 10 deg. / -190 ± 10 deg.)
Experiment 3: Size Reduced Ring Coupler (Operation Frequency: 2400 MHz;
Return Loss: > 25 ± 5 dB; Coupling: < -3 ± 1 dB;
Isolation: > 25 ± 5 dB; Phase difference: 0 ± 10 deg. / -180 ± 10 deg.)
Experiment 4: Miniaturized Ring Coupler (Operation Frequency: 2400 MHz;
Return Loss: > 15 ± 5 dB; Coupling: < -3 ± 1 dB;
Isolation: > 20 ± 5 dB; Phase difference: -3 ± 10 deg. / -175 ± 10 deg.)

Module 6: MPCT-17205-06
Chapter 7: Design and Implementation of Directional Coupler
Experiment 1: Single Stage Directional Coupler (Operation Frequency: 2400 MHz;
Return Loss: > 15 ± 5 dB; Coupling: < -10 ± 1 dB;
Isolation: > 20 ± 5 dB; Phase difference: -90 ± 10 deg.)
Experiment 2: Multi-stages Directional Coupler (Operation Frequency: 2400 MHz;
Return Loss: > 20 ± 5 dB; Coupling: < -6 ± 1 dB;
Isolation: > 20 ± 5 dB; Phase difference: 90 ± 10 deg.)

Chapter 8: Design and Implementation of Balun
Experiment 1: Novel Parallel Line Lange Balun (Operation Frequency: 2400 MHz;
Return Loss: > 15 ± 5 dB; Coupling: < -3 ± 1 dB;
Isolation: > 7 ± 5 dB; Phase difference: -180 ± 10 deg.)
Experiment 2: Multi-stage Coupled Line Balun (Operation Frequency: 2400 MHz;
Return Loss: > 15 ± 5 dB; Coupling: < -3 ± 1 dB;
Isolation: > 7 ± 5 dB; Phase difference: -180 ± 10 deg.)

Module 7: MPCT-17205-07
Chapter 9: Design and Implementation of Low-pass Filter
Experiment 1: Stepped Impedance Low-pass Filter (f-3dB: 2.4 ± 0.1 GHz;
Pass-band Width: > 2.4 ± 0.1 GHz;
-20 dB Band-stop: > 3 ± 0.5 GHz; Return Loss: > 10 ± 5dB;
Insertion Loss: < 0 dB ± 1dB)
Experiment 2: Compact Stepped Impedance Low-pass Filter (f-3dB: 2.4 ± 0.1 GHz;
Pass-band Width: > 2.4 ± 0.1 GHz;
-20 dB Stop-band: > 3 ± 0.5 GHz; Return Loss: > 10 ± 5dB;
Insertion Loss: < 0 dB ± 1dB)
Experiment 3: Branch Line Type Low-pass Filter (f-3dB: 2.4 ± 0.1 GHz;
Pass-band Width: > 2.4 ± 0.1 GHz; -20 dB Stop-band > 3 ± 0.5 GHz;
Return Loss: > 15 ± 5dB; Insertion Loss: < 0 dB ± 1dB)
Experiment 4: Stepped Impedance Hairpin Low-pass Filter (f-3dB: 2.4 ± 0.1 GHz;
Pass-band Width: > 2.4 ± 0.1 GHz; 20 dB Stop-band: > 2.5 ± 0.5 GHz;
Return Loss: > 10 ± 5dB; Insertion Loss: < 0 dB ± 1dB)

Module 8: MPCT-17205-08
Chapter 10: Design and Implementation of BRF and BPF Filters
Experiment 1: Open Stub Band-stop Filter (fc: 2.4 ± 0.1 GHz;
-3 dB Stop-band Width: > 1 ± 0.5 GHz;
-20 dB Stop-band Width: > 1 ± 0.5 GHz;
Return Loss: > 10 ± 5dB; Insertion Loss: < 0 dB ± 1dB)
Experiment 2: Compact Open Stub Band-stop Filter (fc: 2.4 ± 0.1 GHz;
-3 dB Stop-band Width: > 1 ± 0.5 GHz;
-20 dB Stop-band Width: > 1 ± 0.5 GHz;
Return Loss: > 10 ± 5dB; Insertion Loss: < 0 dB ± 1dB)
Experiment 3: Parallel Coupled Line Band-pass Filter (fc: 2.4 ± 0.1 GHz;
Pass-band Width: > 0.5 ± 0.3 GHz;
-20 dB Stop-band Width: > 2 ± 0.5 GHz;
Return Loss: > 10 ± 5dB; Insertion Loss: < 3 dB ± 1dB)
Experiment 4: Wide Stop Band Band-pass Filter with Coupled Line and SIR
Resonator (fc: 2.4 ± 0.1 GHz; Pass-band Width: > 1 ± 0.3 GHz;
-20 dB Stop-band Width: > 3 ± 0.5 GHz; Return Loss: > 10 ± 5dB;
Insertion Loss: < 3 dB ± 1dB)

Module 9: MPCT-17205-09
Chapter 11: PBG Type Filter Design
Experiment 1: Conventional PBG Low-pass Filter (f-3dB: 1.6 ± 0.1 GHz;
-20 dB Stop-band Width: > 1 ± 0.5 GHz;
Return Loss: > 10 ± 5dB; Insertion Loss: < 3 dB ± 1dB)
Experiment 2: Chebyshev PBG Band-stop Filter (f-3dB: 2.4 ± 0.1 GHz;
-3 dB Stop-band Width: > 1 ± 0.5 GHz;
-20 dB Stop-band Width: > 1 ± 0.5 GHz;
Return Loss: > 10 ± 5dB; Insertion Loss: < 2 dB ± 1 dB)

Module 10: MPCT-17205-10
Chapter 12: DGS Type Filter Design
Experiment 1: Low-pass Filter with Periodic DGS (f-3dB: 2.4 ± 0.1 GHz;
-20 dB Stop-band Width: > 3 ± 0.5 GHz;
Return Loss: > 10 ± 5dB; Insertion Loss: < 0 dB ± 1dB)
Experiment 2: SIR Low-pass Filter with DGS (fc: 2.4 ± 0.1 GHz;
-20 dB Stop-band Width: > 3 ± 0.5 GHz;
Return Loss: > 10 ± 5dB; Insertion Loss: < 0 dB ± 1dB)
Experiment 3: Parallel Coupled Line Band-pass Filter with Harmonic Stop
(fc: 2.4 ± 0.1 GHz; Pass-band Width: > 0.3 ± 0.2 GHz;
-20 dB Stop-band Width: > 3 ± 0.5 GHz;
Return Loss: > 10 ± 5dB; Insertion Loss: < 3 dB ± 1 dB)
Experiment 4: Open Stub Band-pass Filter using DGS Loaded (fc: 2.4 ± 0.1 GHz;
Pass-band Width: > 0.4 ± 0.2 GHz;
-20 dB Stop-band Width: > 1 ± 0.5 GHz; Return Loss: > 10 ± 5dB;
Insertion Loss: < 3 dB ± 1 dB)

* Digital storage oscilloscope, function generator, power supply are not included