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GOTT GOTT-MAC-157 超音波主动线路设计培训系统

  • 制造商:GOTT
    Model: GOTT-MAC-157
    P/N: 157-160
    来源: Malaysia
    保障: 12 Month
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PRODUCT MODULES

DESIGN AND MEASUREMENT OF MICROSTRIP LINE MATCHING CIRCUIT - CODE 157-161

Design and Measurement of Microstrip Line Matching Circuit

• Experiment 1: Measurement of λ / 4 Impedance Transformer Matching Network (Operation Frequency: 2400 MHz; S11 < - 10 dB) 

• Experiment 2: Measurement of Single and Balanced Short Stubs Matching Network (Operation Frequency: 2400 MHz; S11 < -10 dB) 

• Experiment 3: Measurement of Single, Balanced and Radio Open Stubs Matching Network (Operation Frequency: 2400 MHz; S11 < -10 dB) 

• Experiment 4: Measurement of and Open Stubs Matching Network (Operation Frequency: 2400 MHz; S11 < -10 dB)

DESIGN AND MEASUREMENT OF LOW NOISE AMPLIFIER & VOLTAGE CONTROLLED OSCILLATOR - CODE 157-162

Design and Measurement of Low Noise Amplifier (LNA) 

• Experiment 1: Measurement of Frequency Responses (Operation Frequency: 2350 ~ 2450 MHz; S11 < -10 dB, S22 < -10 dB, S21 > -10 dB) 

• Experiment 2: Measurement of Noise Figure (Operation Frequency: 2350 ~ 2450 MHz; NF < 1.8 dB) 

• Experiment 3: Measurement of 1 dB Compression Point (Operation Frequency: 2400 MHz; S1dB > -15 dBm)

Design and Measurement of Voltage Controlled Oscillator 

• Experiment 1: Measurement of Oscillation Frequency and Output Power (Oscillation Frequency: 2350~2450 MHz; Output Power: > -5 dBm) 

• Experiment 2: Measurement of Phase Noise (Phase Noise: -90 ~ -100 dBc/Hz @ 100 kHz) 

• Experiment 3: Measurement of Gain Factor and Tunable Bandwidth (Gain Factor: 10 ~20 MHz/Volt; Tunable Bandwidth: 60 ~ 70 MHz) 

• Experiment 4: Measurement of Pushing Figure (Pushing Figure: 8 MHz/Volt)

DESIGN AND MEASUREMENT OF PRE-AMPLIFIER POWER AMPLIFIER - CODE 157-163

Design and Measurement of Pre-amplifier 

• Experiment 1: Measurement of Frequency Responses (Operation Frequency: 2350 ~ 2450 MHz; S11 < -10 dB, S22 < -10 dB, S21 > -10 dB) 

• Experiment 2: Measurement of 1 dB Compression Point (Operation Frequency: 2400 MHz; S1dB > 5 dBm) 

• Experiment 3: Measurement of 3rd Order Intercept Point (Operation Frequency: 2400 MHz; OIP3 > 25 dBm

Design and Measurement of Power Amplifier 

• Experiment 1: Measurement of Gain Flatness (Operation Frequency: 2350 ~ 2450 MHz; Gain Flatness: ±1.5 dB) 

• Experiment 2: Measurement of 1 dB Compression Point (Operation Frequency: 2400 MHz; S1dB > 23 dBm) 

• Experiment 3: Measurement of 3rd Order Output Intercept Point (Operation Frequency: 2400 MHz; OIP3 > 40 dBm) 

• Experiment 4: Measurement of the Ratio of Fundamental and Harmonics (Operation Frequency: 2400 MHz)

DESIGN AND MEASUREMENT OF PHASE LOCKED LOOP CONTROLLER & PHASE LOCKED LOOP - CODE 157-164

Design and Measurement of Phase Locked Loop Controller 

• Experiment 1: LCD and Keypad Testing (Locked Frequency Display: Locked Status Detection) 

• Experiment 2: MB 15E07 Control Signal Testing (Locked Frequency: 2250 ~2350 MHz; Stepped Frequency: 1 MHz, 10 MHz)

Design and Measurement of Phase Locked Loop 

• Experiment 1: Measurement of Frequency Responses for Loop Filter (3-dB Frequency: 12.5 kHz) 

• Experiment 2: Measurement of PLL and Phase Noise (Phase Noise < -100 dBc/Hz @ 100 kHz) 

• Experiment 3: Measurement of PLL Locked Time (Locked Time < 5 ms)

DESIGN AND MEASUREMENT OF BALANCED MIXER & IMAGE-REJECTION MIXER - CODE 157-165

Design and Measurement of Balanced Mixer 

• Experiment 1: Measurement of Conversion Loss vs. LO Power (RF: 2420 MHz, LO: 2350 MHz; Conversion Loss: < 15 dB) 

• Experiment 2: Measurement of Conversion Loss vs. RF Power (RF: 2420 MHz, LO: 2350 MHz; Conversion Loss: < 15 dB, S1dB > 0 dBm) 

• Experiment 3: Measurement of 3rd Order Intercept Point (RF: 2420 MHz, LO: 2350 MHz; OIP3 > 10 dBm) 

• Experiment 4: Measurement of IF bandwidth (RF: 2360 ~ 2450 MHz, LO: 2350 MHz; IF bandwidth: > 100 MHz) 

• Experiment 5: Measurement of Isolation (Operation Frequency: 2350 ~ 2450 MHz; Isolation: > 20 dB)

Design and Measurement of Image-rejection Mixer 

• Experiment 1: Measurement of Conversion Loss vs. LO Power (RF: 2420 MHz; LO: 2350 MHz; Conversion Loss: < 15 dB) 

• Experiment 2: Measurement of Conversion Loss vs. RF Power (RF: 2420 MHz; LO: 2350 MHz; Conversion Loss: < 15 dB, S1dB > 5 dBm) 

• Experiment 3: Measurement of 3rd Order Intercept Point (RF: 2420 MHz; LO: 2350 MHz; OIP3 > 15 dBm) 

• Experiment 4: Measurement of Isolation (Operation Frequency: 2350 ~ 2450 MHz; Isolation: > 30 dB) 

• Experiment 5: Measurement of Image-rejection level (RF: 2250 ~ 2350 MHz; LO: 2350 MHz; Image-rejection level: > 30 dB)

DESIGN AND MEASUREMENT OF IQ MODULATOR & IQ DEMODULATOR - CODE 157-166

Design and Measurement of IQ Modulator 

• Experiment 1: Measurement of PSK Modulator (Operation Frequency: 70.7 MHz; Data Rate: >100 kbps) 

• Experiment 2: Measurement of QPSK Modulator (Operation Frequency: 70.7 MHz; Data Rate: >100 kbps) 

Design and Measurement of IQ Demodulator 

• Experiment 1: Measurement of PSK Demodulator (Operation Frequency: 70.7 MHz; Data Rate: >100 kbps) 

• Experiment 2: Measurement of QPSK Demodulator (Operation Frequency: 70.7 MHz; Data Rate: >100 kbps)

DESIGN AND IMPLEMENTATION OF DIGITAL WIRELESS TRANSMITTER - CODE 157-167

Design and Implementation of Digital Wireless Transmitter 

• Experiment 1: Measurement of Output Power(Operation Frequency: 2400 MHz; Pout > 10 dBm) 

• Experiment 2: Measurement of Harmonics’ Output Power(Operation Frequency: 2400 MHz; Pout < -45 dBm) 

• Experiment 3: Measurement of Modulation Signal (Operation Frequency: 2400 MHz; Type of Modulation: FSK)

DESIGN AND IMPLEMENTATION OF DIGITAL WIRELESS RECEIVER - CODE 157-168

Design and Implementation of Digital Wireless Receiver 

• Experiment 1: Measurement of Sensitivity (Operation Frequency: 2400 MHz; Receiver Sensitivity: > -80 dBm) 

• Experiment 2: Measurement of Demodulation Signal (Operation Frequency: 2400 MHz; Type of Demodulator: FSK) 

• Experiment 3: Measurement of Image-rejection Ability (Operation Frequency: 2400 MHz; Image-rejection level: > 30 dB)

DC POWER SUPPLY & FUNCTION GNERATOR (OPTIONAL ITEM) - - CODE 500-107

DC Power Supply 

• Triple Bipolar Voltage Outputs 

o DC 0 – +/-15V 

o DC +/-5V 

o DC +/-12V 

• Constant & variable Voltage Operation 

• Low Ripple and Noise

Function Generator 

• Two Signals Output Ports 

• Frequency Range: 

FG (I): 0 – 10Hz, 0 – 100kHz, 0 – 1kHz, 0 – 10kHz, 0 – 100kHz 

FG (II): 0 – 100Hz 0 – 1kHz 0 – 10kHz 0 – 100kHz 0 – 1MHz 

• Waveform: Sine, Triangle, Square, TTL Pulse 

• Amplitude: 10Vpp 

• Built-in-6-Digit Frequency Counter 

• Two Large 0.5” LED Display Overload Protection

Manuals: 

(1) All manuals are written in English 

(2) Model Answer 

(3) Teaching Manuals

OPTIONAL: 

DC Power Supply & Function Generator 

Model: GOTT-DC POWER SUPPLY & FUNCTION GENERATOR -  CODE: 500-107

Details

Datasheet


DESCRIPTION 

• Design and implementation of microwave front end receiver module. 

• Design and implementation of microwave front end transmitter module. 

• Design and implementation of voltage controlled oscillator and phase locked loop. 

• Design and implementation of IQ modulator and demodulator. 

• Design and implementation of digital wireless transceiver module

FEATURES

• Training for wireless communication technicians and engineers. 

• To understand the applications and measurements of communication instrument XZs and products. 

• Design and implementation ability training for microwave module circuit. 

• To shorten the gap between academic and industrial circles.

• 2mm connect leads are used throughout the test point. 

• 4mm connect leads are used throughout the DCV point. 

• Each module can interlink together with U-link 4mm for 12v + 12v ground. 

• 4mm LED indicator for each supply DCV + 12 v and -12v or + 5v and 5v.

  • 质量承诺
  • 正品保修
  • 送货到家
  • 交易简单化

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