Complete Beginner's Guide — Themisto TH-M98

Learn Electricity
From Scratch

You just bought your first multimeter. This guide will take you from knowing absolutely nothing about electricity to confidently making real measurements. Let's go.

Safety First
Zero Prior Knowledge Needed
Hands-On Exercises
Your Actual Meter
BAT 9V + LED ON! 220Ω Electrons flow in a complete loop — this is a circuit!

Chapter 1

Safety First — Always

Before touching anything electrical, read this. Electricity can kill. These rules protect you.

Never measure AC mains as a beginner

The 230V in your Indian wall outlet can kill you. Learn on batteries first. When you do eventually measure mains, follow every step in this guide carefully.

🧤

Keep your hands dry

Water conducts electricity. Never use a multimeter with wet hands or near water.

☝️

One hand rule

When measuring high-voltage AC, keep one hand in your pocket. This prevents current from crossing your chest if something goes wrong.

🔍

Check the probes

Before every use, look for cracks or exposed metal on the probe cables. Damaged probes = dangerous.

Start with batteries

AA/AAA/9V batteries are completely safe to measure. They're the perfect learning tool.

What CAT III 600V means on your meter

Your TH-M98 has a "CAT III 600V" rating. This is a safety certification. CAT III means it's rated for measurements in household wiring and distribution boards. It's built with proper internal protection to handle high voltages safely — but that doesn't mean you should rush in. Learn the basics first.

Check which mode your dial is on before connecting probes

One of the most common beginner mistakes is accidentally leaving the meter on Current (A) mode and then measuring voltage. This can blow the internal fuse — or worse. Always double-check your dial setting before probing anything.


Chapter 2

What is Electricity?

Everything is made of atoms. Understanding atoms is the key to understanding electricity.

⚛️ The Atom — the building block of everything

Imagine an atom like a tiny solar system. At the centre is the nucleus (containing protons with a positive charge). Orbiting around it are electrons with a negative charge.

In most materials, electrons are tightly bound to their atoms. But in metals like copper and aluminium, the outermost electrons are very loosely attached — they can break free and drift from atom to atom.

Electricity is simply the movement of these free electrons. When billions of electrons start moving in the same direction through a wire — that's electric current.

✅ Conductors

Materials with free electrons that allow electricity to flow easily. Examples: Copper wire, aluminium, gold, silver, your body (!) — and that's why you can get shocked.

🛑 Insulators

Materials with no free electrons — electricity cannot pass through. Examples: Plastic, rubber, glass, wood, air. This is why wires have plastic coating.

Why does the plastic coating protect you?

The copper wire inside carries electricity. The plastic around it is an insulator — electrons can't escape through plastic, so you can hold a wire safely. If you strip the plastic off and touch the copper, you become part of the circuit!


Chapter 3

Voltage, Current & Resistance

Three things describe every electrical situation. Think of water flowing through a pipe — it's a perfect analogy.

Voltage (V)
"The Push"
Water height = pressure

Like water pressure — the higher the voltage, the harder it pushes electrons.

Measured in Volts (V)
Current (I)
"The Flow"
Flow rate = litres/second

Like how much water flows per second. More current = more electrons moving per second.

Measured in Amps (A)
Resistance (R)
"The Obstacle"
Narrow pipe = restriction

Like a narrow pipe — resistance opposes the flow of electrons.

Measured in Ohms (Ω)
ConceptSymbolUnitReal-world example
VoltageVVolts (V)AA battery = 1.5V · USB = 5V · Wall outlet = 230V
CurrentIAmps (A) or milliamps (mA)LED = 20mA · Phone charging = 2A · Kettle = 10A
ResistanceROhms (Ω), kΩ, MΩLED resistor = 220Ω · Human body (dry) = 100kΩ+
milli = one thousandth

1000 milliamps (mA) = 1 Amp (A). Your meter's 200mA range means it can measure up to 0.2 Amps. Similarly, 1000 millivolts (mV) = 1 Volt.


Chapter 4

Ohm's Law

The most important formula in all of electronics. Three things, one simple relationship.

V = I × R
Voltage = Current × Resistance
V = I × R
Find Voltage
I = V ÷ R
Find Current
R = V ÷ I
Find Resistance

Real example: Connecting an LED to a 9V battery

An LED needs 20mA of current (0.02A) and drops about 2V across itself. Your battery is 9V. How much resistance do you need to protect the LED?

Voltage across resistor = 9V − 2V = 7V
R = V ÷ I = 7 ÷ 0.02 = 350Ω
→ Use a 330Ω or 390Ω resistor (nearest standard values)
⚡ Ohm's Law Calculator
Leave ONE field blank and fill in the other two — then press Calculate.

Chapter 5

AC vs DC

There are two types of electricity. Your meter handles both — but you set the dial differently for each.

DC — Direct Current

Electrons always flow in one direction. Steady, constant. Like water flowing one way through a pipe.

Examples: Batteries, USB chargers, phone batteries, solar panels, your laptop's battery.

Flat line = constant voltage

AC — Alternating Current

Electrons rapidly switch direction back and forth, 50 times per second (50Hz in India).

Examples: Wall outlets (230V), anything you plug into the wall — your fan, TV, fridge.

Sine wave = oscillating voltage
Why does this matter for your meter?

You must set your dial to the correct type. Measuring AC voltage with the dial on DC (or vice versa) will give you a wrong reading. Your TH-M98 has separate positions for AC voltage (V~) and DC voltage (V—) on the dial.


Chapter 6

Your Themisto TH-M98 — Full Tour

Let's identify every part of your meter before you touch anything.

🖥️

LCD Display

Shows your measurement reading. Can display up to 4 digits. Also shows units (V, mA, Ω) and special symbols like OL (overload).

🔘

Rotary Dial

The big knob in the middle. This selects what you're measuring and what range. Always set this BEFORE connecting the probes.

HOLD

HOLD Button (Blue)

Freezes the display so you can read it after removing the probes. Handy in tight spaces where you can't read the screen while probing.

💡

Backlight Button (Blue)

Turns on a backlight so you can read the display in dark areas. The rightmost blue button with the sun/torch icon.

📡

NCV Button

Non-Contact Voltage. Press this while hovering near a wire to detect if it's live — without touching it. The small switch at the top left.

🔌

Transistor Port

The 6-pin socket labeled E B C E / N P near the top. Used to test transistors (an advanced topic for later).

🔋

Battery Compartment

On the back. Contains a 9V battery that powers the meter itself. When the display gets dim, replace it.

TRUE RMS

True RMS

A quality feature. Means your meter gives accurate AC readings even for non-perfect waveforms (like from inverters and dimmers). Most cheap meters don't have this.


Chapter 7

The Dial — Every Position Explained

The dial has zones for different measurements. Here's what each means.

TH-M98 dial with backlight
🔴 OFF
OFF
Turns the meter off. Always set here when not in use to save battery.
📡 NCV
NCV
Non-Contact Voltage detection. Sweep near wires to detect live AC without touching. Beeps and lights up.
⚡ AC Voltage (V~)
600 · 200
Measures alternating current voltage. Use 600 for wall outlets (230V). The wavy line (~) symbol means AC.
🔋 DC Voltage (V—)
600 · 200 · 20 · 2 · 200m
Measures direct current voltage — batteries, USB, etc. Pick the range just above what you expect. The straight line (—) means DC.
🌀 Resistance (Ω)
20M · 2M · 200K · 2K · 200
Measures how much a component opposes current flow. Must be disconnected from power! K = thousands, M = millions of Ohms.
🔔 Continuity / Diode
→|← (with beeper symbol)
Beeps when there's a complete electrical path. Great for testing wires and fuses. Also tests diodes.
⚡ DC Current (A)
10A · 200m · 20m · 2m
Measures current flow. The meter must be placed IN the circuit (in series). Use 10A jack for high currents, VΩmA jack for small currents.
🔬 Transistor hFE
hFE
Tests transistor gain. Use the 6-pin socket at the top. Advanced topic — skip for now.
How to choose the right range

If you don't know the approximate value, start at the highest range. If the reading is too small to be useful (like 0.003 on the 600V range), move down to the next lower range. If you see OL on a lower range, move up. The goal is to get a reading that uses most of the display — like 4.86 is better than 0.005.


Chapter 8

Plugging in the Test Probes

Your meter has two test probes — one red, one black. They plug into specific ports. Get this right every time.

TH-M98 with probes plugged into ports
COM
🖤 Black Probe
Always plug the black probe here. COM = Common = Negative. This is the reference point for all measurements.
VΩmA
🔴 Red Probe (normal use)
Plug the red probe here for measuring voltage, resistance, continuity, and small currents (up to 200mA).
10A
🔴 Red Probe (high current)
Move the red probe here ONLY when measuring currents above 200mA (up to 10A). And set the dial to 10A too!
Golden rule: black in COM, always

The black probe never moves from the COM port. Only the red probe moves between VΩmA and 10A depending on what you're measuring.


Chapter 9

Measuring Voltage

Start here. Measuring battery voltage is the safest, easiest first measurement — and it's genuinely useful.

Exercise: Measure a 9V or AA battery

Plug in your probes

Black probe → COM port · Red probe → VΩmA port. Check this every time.

Set the dial to DC Voltage

Turn the dial to the V— (DC) zone. For a 9V battery, pick the 20 range (since 9V is less than 20). For a 1.5V AA battery, pick the 2 range.

Touch the probes to the battery terminals

Red probe tip → positive (+) terminal of battery · Black probe tip → negative (−) terminal. You can touch both at the same time — it's completely safe with a battery.

Read the display

A healthy 9V battery reads around 9.0 – 9.4V. An AA battery reads 1.4 – 1.6V. A nearly dead battery might read 7.5V (9V type) or 1.1V (AA). Press HOLD to freeze the reading if needed.

Battery TypeDial SettingFresh ReadingReplace When
AAA / AA (1.5V)V— · 2 range1.5 – 1.6VBelow 1.2V
C / D (1.5V)V— · 2 range1.5 – 1.6VBelow 1.2V
9V blockV— · 20 range9.0 – 9.5VBelow 7.5V
CR2032 coin (3V)V— · 20 range3.0 – 3.3VBelow 2.6V
Car battery (12V)V— · 20 range12.6V (full)Below 12.0V

Measuring AC Mains Voltage (Wall Outlet)

Only do this after you're confident — and follow every step

Wall outlets in India are 230V AC. This voltage is lethal. Don't rush this. Only proceed when you feel ready, and never if you're in any doubt.

Set dial to AC Voltage — 600V range

Turn dial to the V~ zone and choose 600. The Indian outlet is 230V, so 600 is the safe range to start.

Hold probes by the insulated handles only

Never touch the metal tips or anything ahead of the finger guards (the plastic ridges on the probes). One hand behind your back or in pocket.

Insert probes one at a time into the outlet

One probe into each slot. For AC voltage, polarity doesn't matter — red or black in either slot is fine.

Read the display

You should see roughly 220 – 240V. That's normal for India. Done! Remove probes carefully, one at a time.


Chapter 10

Measuring Resistance

Resistance tells you how much a component opposes current flow. Super useful for identifying resistors and checking components.

ALWAYS disconnect from power before measuring resistance

Measuring resistance in a live circuit will damage your meter and give wrong readings. The component must be completely unpowered and ideally removed from the circuit.

Set dial to Resistance (Ω)

Pick a range. For a resistor labelled 1kΩ, use the 2K range. For a 47kΩ resistor, use the 200K range. Not sure? Start at 20M and work down.

Touch probes to both ends of the component

For resistance, polarity doesn't matter — you can put either probe on either end. Just touch both ends of the resistor.

Read the display

The number shows the resistance in Ohms (for the range you selected). On the 2K range, a reading of 1.00 means 1.00kΩ = 1000Ω.

Don't touch the metal probe tips with your fingers while measuring

Your body has resistance too (about 100,000Ω when dry). If your fingers bridge the two probe tips, your body resistance gets added to the reading and the result will be wrong.

ComponentExpected ResistanceRange to Use
Short wire / good conductor0 – 2Ω200
LED (won't read like resistor — use diode mode)OL in one directionDiode mode
220Ω resistor~220Ω2K
10kΩ resistor~10kΩ200K
Human body (dry hands)100k – 2MΩ20M
Open circuit (broken wire)OL (infinite)Any

Chapter 11

The Continuity Test

This is one of the most useful functions on the meter. A BEEP means electricity can flow. No beep = broken.

What it does

When you touch the two probes together and place them across something, the meter checks if there's a low-resistance path (less than about 30Ω). If yes, it beeps. You don't need to look at the display — just listen.

Set dial to Continuity

Look for the symbol that looks like a sound wave ))) or the diode arrow →| — they're usually on the same dial position. Your TH-M98 has this at the bottom of the dial.

Touch probes together first

A quick self-test: the meter should beep immediately. This confirms the mode is active and your probes are working.

Touch probes to the component or wire

One probe on each end of a wire or fuse. Beep = good path (current can flow). Silence = open circuit or broken connection.

🔔 BEEP = Good

The wire is continuous, the fuse is intact, the switch is closed. Current can flow through it.

🔇 No Beep = Broken

The wire is broken, the fuse is blown, or the switch is open. Current cannot pass through.

Test an extension cord in 30 seconds

Unplug it. Insert a piece of foil into one socket of the female end connecting two of the pins. Now put probes on the corresponding pins on the male plug. Beep = that wire is good. Test all three wires this way.


Chapter 12

NCV — Non-Contact Voltage Detection

NCV lets you detect live wires without touching them. It's your electric "sixth sense."

How it works

Live AC wires create an electromagnetic field around them (like a tiny radio signal). The NCV sensor in your TH-M98's tip picks up this field. When it detects AC voltage, the meter beeps and the NCV LED lights up.

It only detects AC (like wall outlet power). It cannot detect DC (batteries won't trigger it).

Switch the NCV toggle to ON

There's a small slider switch near the top-left of your TH-M98 labelled NCV. Slide it to the active position. The dial can be on any setting.

Hold meter near the wire or outlet

Point the top of the meter (the probe tip end) toward the wire. Move it slowly closer.

Listen and watch

Beeping + LED flashing = AC voltage detected. The faster it beeps, the stronger the field (i.e., you're closer). No beep = no live AC there.

NCV is a detector, not a meter

NCV tells you YES there's voltage / NO there isn't. It doesn't tell you how many volts. It can also give false positives near transformers or other electromagnetic sources. Always confirm with an actual voltage measurement when safety matters.


Chapter 13

Reading the Display

The LCD can show different things. Here's what they all mean.

OL

Overload — the reading is higher than the range can handle. Switch to a higher range (e.g., from 20V to 200V).

−14.7

Negative reading — you've got the probes reversed. Swap red and black. (Harmless, just informational.)

0.00

Zero — no voltage/resistance detected, or component is a short circuit. Check connections and try again.

1.483

Normal reading — this is 1.483 in whatever units the dial is set to. On the 2V range, that's 1.483 Volts.

HOLD

Hold indicator — appears when you press HOLD. The reading is frozen. Press HOLD again to resume live readings.

🔋 LO BAT

Low battery — the 9V battery inside the meter is running out. Replace it (accessible from the back panel).

Understanding the decimal point

On the 20V DC range, a reading of 9.12 means 9.12 Volts. On the 200V range, 9.1 means 9.1 Volts (less precision). The lower the range, the more decimal places — and the more precise your reading.


Chapter 14

Beginner Projects

Put your knowledge to work. These are real tasks you can do right now with your TH-M98 and things you likely have at home.

PROJECT 01
The Great Battery Audit
Go through every battery in your house — TV remotes, clocks, toys. Test each one and sort into "good," "ok," and "dead" piles. You'll probably find a few surprises.
DC Voltage · V— · 2V range
PROJECT 02
Fuse Inspector
Car fuses are easy to grab. Use continuity mode to test a known-good fuse (beep), then bend one to break it and confirm no beep. Now you know how to spot a blown fuse.
Continuity · )))
PROJECT 03
Resistance of Everything
Measure resistance of: a pencil line drawn on paper, tap water in a glass, a rubber eraser, your dry hand, your wet hand. Compare the numbers — you'll understand conductors vs insulators instantly.
Resistance · Ω
PROJECT 04
Is That Wire Live?
Use NCV mode to map which wires in a power strip are live, and which slots of a multi-plug carry power. Great for understanding what's connected to what before unplugging things.
NCV Detection
PROJECT 05
Voltage Drop Through Resistors
Connect two resistors in series to a 9V battery. Measure voltage across the battery, then across each resistor. Add them up — they should equal the battery voltage. Ohm's law in action!
DC Voltage · Ohm's Law
PROJECT 06
Continuity Map an Extension Cord
With the cord unplugged, test continuity from each pin at the plug to the corresponding socket at the other end. All three should beep. Find a dodgy cord before it becomes a fire hazard.
Continuity · Safety

Reference

Glossary

Every term used in this guide — explained simply.

AC (Alternating Current)
Current that constantly reverses direction. What comes from your wall outlet. 50 times per second in India.
Amp / Ampere (A)
Unit of current (electron flow). 1 Amp = 6.24 billion billion electrons per second flowing past a point.
CAT Rating
Safety category for measurement equipment. CAT III (on your meter) means it's rated for building wiring and distribution boards.
Circuit
A complete loop that electricity can flow around. Electricity needs a complete path — break the loop and it stops.
COM
Common — the reference jack on your meter. Always plug the black probe here.
Conductor
A material that allows electricity to flow easily. Metals like copper and aluminium are good conductors.
Continuity
When there's a continuous electrical path between two points. A beeping meter = continuity = current can flow.
Current (I)
The flow rate of electrons through a wire. Measured in Amps (A) or milliamps (mA).
DC (Direct Current)
Current that flows in one direction only. Batteries produce DC. Steady and constant.
Diode
A component that only allows current to flow in one direction — like a one-way valve. LEDs are a type of diode.
Ground (GND)
The reference point in a circuit — usually the negative terminal of a battery or the earth connection in mains wiring.
hFE
Transistor gain — how much a transistor amplifies current. Measured by your meter's hFE port/mode.
Insulator
A material that blocks electricity. Plastic, rubber, and glass are insulators — that's why wires have plastic coating.
kΩ (Kilohm)
1,000 Ohms. A 10kΩ resistor = 10,000 Ohms.
mA (milliamp)
One thousandth of an Amp. LEDs typically need 20mA. 1000mA = 1A.
MΩ (Megaohm)
1,000,000 Ohms. Human skin resistance is often in the megaohm range when dry.
mV (millivolt)
One thousandth of a Volt. 1000mV = 1V. Your meter can measure down to this precision.
NCV
Non-Contact Voltage. Detects AC voltage nearby without touching the wire. Your meter beeps when it senses a live wire.
Ohm (Ω)
Unit of resistance. Named after Georg Simon Ohm, who discovered V = I × R.
Ohm's Law
V = I × R. Voltage equals current times resistance. The foundational law of electronics.
OL (Overload)
The reading is beyond the selected range. Switch to a higher range on the dial.
Open Circuit
A broken loop — electricity can't flow. A blown fuse creates an open circuit.
Resistance (R)
How much a material opposes the flow of current. Measured in Ohms (Ω).
Short Circuit
An accidental direct connection between + and − with very low resistance. Causes huge current, heat, and fire risk.
True RMS
A measurement method that gives accurate AC readings for any waveform shape — not just perfect sine waves.
Volt (V)
Unit of voltage (electrical pressure). Named after Alessandro Volta, inventor of the battery.
Voltage (V)
The electrical "push" or pressure difference that makes electrons move. Higher voltage = stronger push.
You're ready to start exploring
Begin with the battery projects. Every measurement you make teaches you something real. The best way to learn electricity is to actually measure it.