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Digitour Multimeter Q1467 Manual Lawn카테고리 없음 2020. 2. 19. 05:05
How do I use a? This tutorial will show you how to use a digital multimeter (DMM), an indispensable tool that you can use to diagnose circuits, learn about other people's electronic designs, and even test a battery. Hence the 'multi'-'meter' (multiple measurement) name.The most basic things we measure are voltage and current. A multimeter is also great for some basic sanity checks and troubleshooting. Is your circuit not working?
Does the switch work? Put a meter on it!
The multimeter is your first defense when troubleshooting a system. In this tutorial we will cover measuring and continuity.Suggested ReadingThese concepts may be helpful with this tutorial:. A multimeter is has three parts:. Display.
Multimeter Instruction Manual
Selection Knob. PortsThe display usually has four digits and the ability to display a negative sign. A few multimeters have illuminated displays for better viewing in low light situations.The selection knob allows the user to set the multimeter to read different things such as milliamps (mA) of, (V) and (Ω).Two probes are plugged into two of the ports on the front of the unit. COM stands for common and is almost always connected to Ground or ‘-’ of a circuit.
The COM probe is conventionally black but there is no difference between the red probe and black probe other than color. 10A is the special port used when measuring large currents (greater than 200mA). MAVΩ is the port that the red probe is conventionally plugged in to. This port allows the measurement of current (up to 200mA), voltage (V), and resistance (Ω).
The probes have a banana type connector on the end that plugs into the multimeter. Any probe with a banana plug will work with this meter.
This allows for different to be used. Measuring VoltageTo start, let's measure voltage on a AA battery: Plug the black probe into COM and the red probe into mAVΩ. Set the multimeter to '2V' in the DC (direct current) range. Almost all portable electronics use ), not. Connect the black probe to the battery's ground or '-' and the red probe to power or '+'.
Squeeze the probes with a little pressure against the positive and negative terminals of the AA battery. If you've got a fresh battery, you should see around 1.5V on the display (this battery is brand new, so its voltage is slightly higher than 1.5V).
Measuring the voltage coming off of a Power Supply Stick.Set the knob to '20V' in the DC range (the DC Voltage range has a V with a straight line next to it). Multimeters are generally not autoranging. You have to set the multimeter to a range that it can measure. For example, 2V measures voltages up to 2 volts, and 20V measures voltages up to 20 volts. So if you've measuring a 12V battery, use the 20V setting. Use the 20V setting.
If you set it incorrectly, you will probably see the meter screen change and then read '1'. With some force (imagine poking a fork into a piece of cooked meat), push the probes onto two exposed pieces of metal. One probe should contact a GND connection. One probe to the VCC or 5V connection.We can test different parts of the circuit as well. This practice is called, and it is a basic building block in circuit analysis. By measuring the voltage across the circuit we can see how much voltage each component requires.
Let's measure the whole circuit first. Measuring from where the voltage is going in to the resistor and then where ground is on the LED, we should see the full voltage of the circuit, expected to be around 5V. This LED is using 2.66V of the available 5V supply to illuminate. This is lower than the forward voltage stated in the on account of the circuit only having small amount of current running though it, but more on that in a bit. OverloadWhat happens if you select a voltage setting that is too low for the voltage you're trying to measure? The meter will simply display a 1. This is the meter trying to tell you that it is overloaded or out-of-range.
Whatever you're trying to read is too much for that particular setting. Try changing the multimeter knob to a the next highest setting. In general, stick to DC circuits (the settings on the multimeter with straight lines, not curvy lines). Most multimeters can measure AC (alternating current) systems, but AC circuits can be dangerous. A wall outlet with AC or 'main voltage' is the stuff that can zap you pretty good. VERY carefully respect AC.
If you need to check to see if an outlet is 'on' then use a. Really the only times we've needed to measure AC are when we've got an outlet that is acting funny (is it really at 110V?), or if we're trying to control a heater (such as a ). Go slow and double check everything before you test an AC circuit. The meter will read one of three things, 0.00, 1, or the actual resistor value.In this case, the meter reads 0.97, meaning this resistor has a value of 970Ω, or about 1kΩ (remember you are in the 20kΩ or 20,000 Ohm mode so you need to move the decimal three places to the right or 970 Ohms).If the multimeter reads 1 or displays OL, it's overloaded. You will need to try a higher mode such as 200kΩ mode or 2MΩ (megaohm) mode. There is no harm if this happen, it simply means the range knob needs to be adjusted.If the multimeter reads 0.00 or nearly zero, then you need to lower the mode to 2kΩ or 200Ω.Remember that many resistors have a 5% tolerance.
This means that the color codes may indicate 10,000 Ohms (10kΩ), but because of discrepancies in the manufacturing process a 10kΩ resistor could be as low as 9.5kΩ or as high as 10.5kΩ. Don't worry, it'll work just fine as a pull-up or general resistor.Let's drop the meter down to the next lowest setting, 2K&ohm.
What happens? Now, since 1kΩ is greater than 200Ω, we've maxed out the meter, and it is telling you that it is overloaded and that you need to try a higher value setting.As a rule of thumb, it's rare to see a resistor less than 1 Ohm. Remember that measuring resistance is not perfect. Temperature can affect the reading a lot.
Also, measuring resistance of a device while it is physically installed in a circuit can be very tricky. The surrounding components on a circuit board can greatly affect the reading. Measuring CurrentReading current is one of the trickiest and most insightful readings in the world of embedded electronics. It's tricky because you have to measure current in.
Where voltage is measure by poking at VCC and GND (in ), to measure current you have to physically interrupt the flow of current and put the meter in-line. To demonstrate this, we'll use the same circuit we used in the measuring voltage section.The first thing we'll need is an extra piece of wire.
As mentioned, we'll need to physically interrupt the circuit to measure the current. Said another way, pull out the VCC wire going to the resistor, add a wire where that wire was connected, and then probe from the power pin on the power supply to the resistor. This effectively 'breaks' power to the circuit. We then insert the multimeter in-line so that it can measure the current as it 'flows' through to the multimeter into the bread board.For these pictures, we cheated and used.
When measuring current, it's often good to watch what your system does over time, for a few seconds or minutes. While you might want to stand there and hold the probes to the system, sometimes it's easier to free up your hands. These alligator clip probes can come in handy.
Note that almost all multimeters have the same sized jacks (they're called 'banana plugs') so if you're in a pinch, you can use your friend's probes. With the multimeter connected, we can now set the dial to the proper setting and measure some current. Measuring current works the same as voltage and resistance - you have to get the correct range. Set the multimeter to 200mA, and work from there. The current consumption for many breadboard projects is usually under 200mA. Make sure the red probe is plugged into the 200mA fused port.
On our favorite, the 200mA hole is the same port/hole as voltage and resistance reading (the port is labeled mAVΩ). This means you can keep the red probe in the same port to measure current, voltage, or resistance. However, if you suspect that your circuit will be using close to or more than 200mA, switch your probe to the 10A side, just to be safe. Overloading the current can result in a blown fuse rather than just an overload display. More on that in a bit. This circuit was only pulling 1.8mA at the time of measurement, not a lot of current. The average reading was closer to 2.1mA.Realize that the multimeter is acting as a piece of wire - you've now completed the circuit, and the circuit will power on.
This is important because as time goes on the LED, microcontroller, sensor, or whatever device being measured may change its power consumption (such as turning on an LED can resulting in a 20mA increase for a second, then decrease for a second when it turns off). On the multimeter display you should see the instantaneous current reading. All multimeters take readings over time and then give you the average, so expect the reading to fluctuate. In general, cheaper meters will average more harshly and respond more slowly, so take each reading with a grain of salt.
In your head, take an average range such as 7 to 8mA under normal 5V conditions (not 7.48mA).Similar to the other measurements, when measuring current, the color of the probes does not matter. What happens if we switch probes? Nothing bad happens! It simply causes the current reading to become negative. When you're done using the meter, always return the meter to read voltage (return the probes to the voltage port, set the meter to read the DC voltage range if necessary).
It's common to grab a meter and begin to quickly measure the voltage between two pins. If you have left your meter in 'current' mode, you won't see the voltage on the display. Instead you'll see '0.000' indicating that there is no current between VCC and GND. Within that split second you will have connected VCC to GND through your meter and the 200mA fuse will blow = not good.
So before you put the meter down for the night, remember to leave your meter in a friendly state.Measuring current can be tricky the first couple of times. Don't worry if you blow the fuse - we've done it dozens of times! We'll show you how to replace the fuse in a.
ContinuityContinuity testing is the act of testing the resistance between two points. If there is very low resistance (less than a few Ωs), the two points are connected electrically, and a tone is emitted. If there is more than a few Ωs of resistance, than the circuit is open, and no tone is emitted. This test helps insure that connections are made correctly between two points.
This test also helps us detect if two points are connected that should not be.Continuity is quite possibly the single most important function for embedded hardware gurus. This feature allows us to test for conductivity of materials and to trace where electrical connections have been made or not made.Set the multimeter to 'Continuity' mode. It may vary among DMMs, but look for a diode symbol with propagation waves around it (like sound coming from a speaker). In general, turn OFF the system before checking for continuity.On a breadboard that is not powered, use the probes to poke at two separate ground pins. You should hear a tone indicating that they are connected. Poke the probes from the VCC pin on a microcontroller to VCC on your power supply.
It should emit a tone indicating that power is free to flow from the VCC pin to the micro. If it does not emit a tone, then you can begin to follow the route that copper trace takes and tell if there are breaks in the line, wire, breadboard, or PCB.Continuity is a great way to test if two SMD pins are touching. If your eyes can't see it, the multimeter is usually a great second testing resource.When a system is not working, continuity is one more thing to help troubleshoot the system. Here are the steps to take:. If the system is on, carefully check VCC and GND with the voltage setting to make sure the voltage is the correct level. If the 5V system is running at 4.2V check your regulator carefully, it could be very hot indicating the system is pulling too much current.
Power the system down and check continuity between VCC and GND. If there is continuity (if you hear a beep), then you've got a short somewhere. Power the system down. With continuity, check that VCC and GND are correctly wired to the pins on the microcontroller and other devices.
The system may be powering up, but the individual ICs may be wired wrong. Assuming you can get the microcontroller running, set the multimeter aside, and move on to serial debugging or use a logic analyzer to inspect the digital signals.Continuity and large capacitors: During normal troubleshooting. You will be probing for continuity between ground and the VCC rail. This is a good sanity check before powering up a prototype to make sure there is not a short on the power system.
But don't be surprised if you hear a short 'beep!' When probing. This is because there is often significant amounts of capacitance on the power system. The multimeter is looking for very low resistance to see if two points are connected. Capacitors will act like a short for a split second until they fill up with energy, and then act like an open connection. Therefore, you will hear a short beep and then nothing.
That's ok, it's just the caps charging up. Changing the FuseOne of the most common mistakes with a new multimeter is to measure current on a bread board by probing from VCC to GND (bad!). This will immediately short power to ground through the multimeter causing the bread board power supply to brown out. As the current rushes through the multimeter, the internal fuse will heat up and then burn out as 200mA flows through it. It will happen in a split second and without any real audible or physical indication that something is wrong.Wow, that was neat.
Well first, remember that measuring current is done in series (interrupt the VCC line to the breadboard or microcontroller to measure current). If you try to measure the current with a blown fuse, you'll probably notice that the meter reads '0.00' and that the system doesn't turn on like it should when you attach the multimeter.
This is because the internal fuse is broken and acts as a broken wire or open. Don't worry, this happens all the time, and it costs to fix.To change the fuse, find your handy dandy, and start taking out screws. The SparkFun DMM is pretty easy to pull apart. Start by removing the battery plate and the battery. DO NOT put a 10A fuse where a 200mA fuse should go.
The placement of the fuses may not match the placement of the probe ports. Read the metal cap on either end of the fuse to double check which is which.The components and PCB traces inside the multimeter are designed to take different amounts of current. You will damage and possibly ruin your multimeter if you accidentally push 5A through the 200mA port.There are times where you need to measure high current devices like a motor or heating element. Do you see the two places to put the red probe on the front of the multimeter?
10A on the left and mAVΩ on the right? If you try to measure more than 200mA on the mAVΩ port you run the risk of blowing the fuse.
But if you use the 10A port to measure current, you run a much lower risk of blowing the fuse. The trade-off is sensitivity. As we talked about above, by using the 10A port and knob setting, you will only be able to read down to 0.01A or 10mA. Most of my systems use more than 10mA so the 10A setting and port works well enough.
If you're trying to measure very low power (micro or nano amps) the 200mA port with the 2mA, 200uA, or 20uA could be what you need. Remember: If your system has the potential to use more than 100mA you should start with the red probe plugged into the 10A port and 10A knob setting.With sub $50 digital multimeters, the measurements you are likely to take are just trouble shooting readings, not scientific experimental results. If you really need to see how the IC uses current or voltage over time, use an or other high quality bench unit. These units have higher precision and offer a wide range of fancy functions (some!)., hardware designer behind, uses high-precision current readings to trouble shoot boards during the final testing procedures of a Chumby. By looking at the current consumption of different boards that have failed (for example a given failed board uses 210mA over the normal), he could identify what was wrong with the board (when the RAM fails, it generally uses 210mA over normal).
By pinpointing what may be potentially wrong, the rework and repair of boards is made much easier. There are fancy multimeters that are autoranging, meaning they automatically change their internal range to attempt to find the correct voltage, resistance, or current of the thing you're poking at.
Auto-ranging can be very helpful if you know how to use it. Generally speaking, autoranging multimeters are higher quality and generally have more features. So if someone gives you a multimeter with auto-range, put it to use!
Just know how to get it into manual mode. A circuit's voltage or current can fluctuate quite quickly. With some of the systems, the current or voltage is so sporadic that the auto-range can't keep up sensibly.A back-lit LCD is fancy, but when was the last time you measured your circuit in the dark? We generally steer clear of scary forests and situations that require us to test stuff in the middle of the night, but some people may want or need a dark-friendly multimeter.A good click on the range selector is actually a major plus in our book. A soft knob is usually indicative of a shoddy meter.Decent probes are a plus. Over time the leads will tend to break down at the flex point.
We've seen wires come completely out of probes - and it's always at the moment you need the probes to work! If you do break a probe, they are reasonably.Auto-off is a great feature that is rarely seen on cheaper multimeters. This is a feature that can benefit beginners and advanced users alike, as it's easy to forget to turn the meter off at 2AM. The doesn't have this feature, but luckily the meter is very low-power. We've left the multimeter for two days straight before the 9V battery began to get low. That said, don't forget to turn your meter off!You're now ready to use your digital multimeter to start measuring the world around you.
Feel free to start using it to answer many questions. I believe my LED is getting 20mA, is it really?
How much voltage does a lemon have? Is a glass of water conductive? Can I use aluminum foil to replace these wires? A digital multimeter will answer these and many more questions about electronics.