Comparison UNI-T UT203+ vs Protester PM2118

The upper limit of the lower sub-range in which the device can measure DC voltage (see "Type of voltage").

The operating ranges of modern multimeters and other measuring instruments are usually divided into subranges. This is done for accuracy and convenience when measuring: for example, to assess the quality of AA batteries, you can set the subrange “up to 3 V” — this will give an accuracy of up to tenths, or even hundredths of a volt, unattainable when measuring with a higher threshold. The minimum constant voltage describes exactly the lower subrange, designed to measure the smallest voltage values: for example, if 2000 mV is indicated in this paragraph, this means that the lower subrange covers values \u200b\u200bup to 2000 mV (i.e. up to 2 V).

It is worth choosing according to this indicator taking into account the specifics of the planned application: for example, a device with low rates can be useful for delicate work, such as repairing computers or mobile phones, but for servicing the on-board electrical network of a car, especially high voltage sensitivity is not required.

The upper limit of the lower sub-range in which the device can measure AC voltage (see "Type of voltage").

The operating ranges of modern multimeters and other measuring instruments are usually divided into subranges. This is done for accuracy and convenience in measurements: for example, to test a transformer that should output 6 V, it makes sense to set a subrange with an upper threshold of 10 V. This will ensure accuracy up to tenths of a volt, unattainable when measuring with a higher threshold. The minimum constant voltage describes exactly the lower subrange, designed to measure the smallest voltage values: for example, if 2000 mV is indicated in this paragraph, this means that the lower subrange covers values \u200b\u200bup to 2000 mV (i.e. up to 2 V).

If the device is purchased for measurements in stationary networks — household at 230 V or industrial at 400 V — you can ignore this parameter: usually, the minimum subranges are not used. But to work with power supplies, step-down transformers and various “thin” electronics served by low voltage alternating current, it makes sense to choose a model with a lower minimum voltage. This is connected not only with the measurement range: a low threshold, usually, indicates a good measurement accuracy at low voltages in general.

The upper limit of the lower sub-range in which the device can measure direct current (see "Type of current").

The operating ranges of modern multimeters and other measuring instruments are usually divided into subranges. This is done for accuracy and convenience in measurements: the lower the subrange, the smaller values it covers, the higher the measurement accuracy at low current values. The minimum direct current describes exactly the lower range, designed for the weakest current values: for example, if the characteristics in this paragraph indicate 500 μA, this means that the lower subrange allows you to measure currents from 0 to 500 μA.

It is worth choosing according to this indicator taking into account the specifics of the planned application: for example, a device with low rates can be useful for delicate work, such as repairing computers or mobile phones, but for servicing the on-board electrical network of cars, especially old ones, especially high current sensitivity is not required.

The highest direct current (see “Type of current”) that the device is able to measure without overloads and related troubles (such as “flying” fuses or even failure).

When choosing for this parameter, it is worth remembering that even at relatively low voltages, the currents can be quite high if the power source provides the appropriate power — for example, a 12 V car battery is quite capable of delivering currents of hundreds of amperes. Actually, compatibility with high direct currents is important primarily for automotive devices; however, the matter is not limited to this.

For safe use, it is desirable to have a certain margin for maximum current. Also, do not forget that before measurements you need to set the appropriate settings.

The largest alternating current (see "Type of current") that can be measured with this device. In no case should this parameter be exceeded — otherwise various troubles are possible, from the operation of the device's emergency protection (with further replacement of fuses) to fire.

When choosing for this parameter, it is worth remembering that even at relatively low voltages, the currents can be quite high if the power supply provides adequate power. For safe use, it is desirable to have a certain margin for maximum current. Also, do not forget that before measurements you need to set the appropriate settings.

The upper limit of the lower sub-range in which the device can measure resistance.

The operating ranges of modern multimeters and other measuring instruments are usually divided into subranges. This is done for accuracy and convenience in measurements: the lower the subrange, the smaller the values it covers, the higher the accuracy of measurements at low resistance values. The minimum resistance describes exactly the lower range, designed for the weakest current values: for example, if the characteristics in this paragraph indicate 500 Ohms, this means that the lower subrange allows you to measure resistance from 0 to 500 Ohms.

When choosing for this indicator, you need to consider how important it is for you to accurately measure small resistances. At the same time, we note that the 500 Ohms given in the example are a fairly good indicator, indicating a fairly solid resistance measurement accuracy; in relatively inexpensive multimeters, this indicator can be 2.5 or even 10 kΩ, which ensures accuracy at best up to several tens of ohms.

The highest resistance that the instrument can effectively measure.

When choosing according to this indicator, you must first take into account the largest resistances that are supposed to be measured. And if we are talking about an analogue device (see "Type"), you must also remember that as you approach the maximum resistance, the measurement accuracy drops sharply. This is due to the peculiarities of measuring and grading the scale in such devices: for example, with a maximum resistance of 1 MΩ, the division value in the range of 0 – 2 kΩ can be 0.2 kΩ, in the range of 2 – 6 kΩ — 0.5 kΩ, in the range of 6 – 10 kOhm — already 1 kOhm, and closer to the maximum this figure can reach tens and even hundreds of kilo-ohms. Therefore, it is worth choosing an analogue device in such a way that its maximum resistance is at least 10 times higher than the largest resistances that are planned to be measured — only under this condition is a more or less acceptable measurement accuracy ensured.

The distance that the tips of the jaws of the measuring instrument can open relative to each other. Relevant for current clamp metres.

The diagonal of the display used in the instrument.

Digital models are equipped with displays (see "Type"), and for an oscilloscope, this item of equipment is mandatory regardless of type. Actually, the diagonal of the display is important primarily for oscilloscopes and scopmeters (see "Device"): the larger the display, the more accurate and convenient for perception the signal graph displayed on it and other parameters. On the other hand, a screen that is too large will cost a lot, and will also significantly affect the overall dimensions of the entire device. Therefore, the best compromise for such devices is considered to be a diagonal of 5 – 6 "— it allows you to get quite clear data and at the same time does not lead to a significant increase in the price and dimensions of the device.

For classic multimeters, the display size is not so critical, besides, manufacturers try to select the screen in such a way that it is not too large and at the same time convenient enough to read the readings. Therefore, in such cases, the screen size may not be indicated at all.