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Measurement Instruments and Tools
Multimeter
Basic Functions
Voltage Measurement (V):
DC (DCV): Connect in parallel across the points being measured
AC (ACV): Connect in parallel; displays RMS value (True RMS meters are more expensive)
Current Measurement (A):
Must be connected in series! Move probes to the A/mA jack
Remember to switch back to the V jack after measuring (otherwise, the next voltage measurement will cause a short circuit!)
Resistance Measurement (Ω):
Measure with power off! Cannot measure in-circuit
Continuity Test (Beep Mode):
R < ~50Ω triggers beep → Quick check for connections/short circuits
Usage Precautions
1. After measuring current, you must move the probes back to the V/Ω jacks!
Forgetting to switch back → Next voltage measurement will cause a direct short → Blows fuse/damages meter
2. Use one hand when measuring high voltage (>30V) (keep the other hand in your pocket)
Prevents current from flowing through the heart
3. Discharge high-voltage capacitors before touching them
4. High-impedance digital meters may induce "ghost voltage"
Floating wires can pick up surrounding electric fields → Display shows a number, but it does not represent actual voltage
Oscilloscope
Core Parameters
Bandwidth:
Determines the highest frequency you can see
Rule of thumb: Bandwidth ≥ 5× signal frequency (for square waves)
Bandwidth ≥ 3× signal frequency (for sine waves)
Example: To view a 20MHz square wave → Need at least 100MHz bandwidth
(3rd/5th harmonics of the square wave must be displayed correctly)
Sample Rate:
Determines time resolution
Rule of thumb: Sample rate ≥ 2.5× bandwidth (Nyquist is not enough)
Example: 100MHz bandwidth → At least 250MSa/s, recommended 1GSa/s
Memory Depth:
Determines how long a capture can be
Record duration = Memory Depth / Sample Rate
1Mpts @ 1GSa/s = 1ms
Probes
1x Probe: Signal passes through directly (1:1)
Bandwidth limited (~20MHz), high input capacitance
10x Probe: Signal attenuated by 10x
Higher bandwidth, lower input capacitance → **Use this by default!**
Must be calibrated (adjust compensation capacitor on the probe)
Measure high voltage (>40V) → Use differential or isolated probes
Measure current → Current probe
Basic Operations
Trigger:
Determines when the waveform starts displaying
Common: Rising edge trigger, Level trigger
Unstable trigger → Waveform runs across the screen
Coupling:
DC: Displays full signal (AC+DC)
AC: Filters out DC component, shows only AC
Must use AC coupling for measuring power supply ripple!
Single Capture:
Captures once and stops; used for capturing sporadic events/power-on sequences
Keep probe ground leads as short as possible!
Long ground leads → Antenna effect → Introduces high-frequency noise
Common Measurement Scenarios
1. Power Supply Ripple:
AC coupling, 20MHz bandwidth limit, short ground spring
2. Clock/Crystal:
10x probe, place on crystal pins (not on load capacitors)
3. Serial Signals:
Decode function: Automatic decoding of UART/I2C/SPI
4. MOSFET Switching:
Use differential probe to measure Vgs and Vds simultaneously → Observe switching losses
Logic Analyzer
Difference from Oscilloscope:
Oscilloscope: Views analog waveforms (voltage vs. time)
Logic Analyzer: Views digital timing (0/1 vs. time)
Advantages: Many channels (8/16/32), protocol decoding, long-duration recording
Limitations: Only sees 0/1, cannot see signal quality
Budget Option: Saleae clone (24MHz/8ch) $10
Recommended: DSLogic Plus / Saleae Logic
Typical Usage
Capture SPI (4 lines) + I2C (2 lines) + UART (2 lines) simultaneously
→ Observe timing relationships between buses
Trigger Conditions: Specific protocol packets / Specific logic level sequences
Bench Power Supply
Constant Voltage (CV): Voltage is fixed, current adjusts automatically
Constant Current (CC): Current is fixed, voltage adjusts automatically
First Power-On:
1. Set voltage → Set current limit → Output OFF
2. Connect wires → Check for no short circuits
3. Output ON → Observe if current is normal
Current Limit = The Poor Man's Protection!
Set a low current limit first, confirm normal operation, then increase
Function Generator
Common Waveforms: Sine, Square, Triangle, Sawtooth, Arbitrary
Uses:
- Inject test signals
- Simulate sensor outputs
- Frequency response testing
Note: Output impedance is typically 50Ω
Connecting to a high-impedance load → Output voltage will be 2x the displayed value!
Soldering Tools
Soldering Iron
Temperature: Lead-tin 300~330°C, Lead-free 350~380°C
Constant Temperature Station (T12/C245) >> Standard Soldering Iron
Iron Tip Maintenance: Keep tinned, clean with brass wool
Do NOT sand the tip!
Solder
Lead (63/37 SnPb): 183°C melting point, easy to solder but toxic
Lead-free (SAC305): 217°C melting point, eco-friendly but harder to solder
Flux: Rosin or no-clean flux (extra flux helps significantly)
Soldering Techniques
1. Tin the tip → Preheat pad → Add solder → Remove solder → Remove iron
Entire process takes 1-3 seconds
2. Heat the pad and pin, not the solder
3. QFP/QFN Packages:
Drag Soldering: Use plenty of flux, drag the chisel tip
Hot Air Gun: Essential for BGA/QFN
4. Post-solder Inspection: Inspect each pin with a magnifying glass, check for shorts with a multimeter
ESD Protection
Wrist Strap: Must be grounded! (via 1MΩ resistor)
Desk: Anti-static mat
Storage: Store ICs in anti-static bags/conductive foam
MOSFETs/CMOS ICs are extremely sensitive to static electricity!
(Static electricity you might not even feel is enough to break down the gate oxide layer)
Golden Rules:
- Touch a grounded object before soldering
- Hold ICs by the edges only (do not touch pins)
- Be especially careful in dry weather
Keywords: Multimeter, Oscilloscope, Probe, Trigger, Logic Analyzer, Soldering, ESD, Bench Power Supply