The EMG signal is the summation of

The EMG signal is the summation of the discharges of all the motor units within the pick-up range of the electrode. During a sustained weak contraction, a needle electrode might detect two motor units discharging independently at rates of about ten discharges per second. The EMG signal will consist of two distinct trains of MUAPs. Most of the MUAPs will be clearly recognizable. Occasionally, though, the two motor units may discharge at nearly the same time, and the two MUAPs will overlap one another. This is called a superposition. The resultant waveform can be either larger or smaller than the individual MUAPs, depending on whether the overlap results in constructive or destructive interference.

During a somewhat stronger contraction, the EMG signal might contain MUAP trains from four to eight nearby motor units and several more distant ones, with discharge rates ranging up to fifteen discharges per second. The individual MUAPs will be difficult to sort out because of the high number of superpositions. The MUAPs from the nearby motor units can be enhanced by high-pass filtering. This accentuates their spikes, making them sharper and narrower, and, at the same time, attenuates the duller, broader MUAPs from the more distant motor units. Even though the spikes from the nearby motor units are narrow, they tend to retain their individuality. In fact, different motor units can usually be distinguished by their spikes more reliably than by their unfiltered MUAPs.

The EMG signal from an even stronger contraction might contain so much activity that even after high-pass filtering the individual MUAP trains cannot be identified with any degree of reliability. The complexity of an EMG signal depends on the strength of the contraction, whether the strength remains constant or not (isotonic or non-isotonic), whether the length of the muscle remains constant or not (isometric or non-isometric), and the type of electrode.

The three main categories of electrodes used to record EMG signals are needle electrodes, fine-wire electrodes, and surface electrodes. Needle electrodes have the advantage that they can be manipulated within the muscle to sample different parts of the muscle and to optimize signal characteristics. Fine-wire electrodes are typically inserted with a hypodermic needle. The ends of the wires remain in the muscle while the wires pass through the skin to connect to the amplifier. One advantage of fine-wire electrodes is that they tend to remain in place well throughout a long experiment.

The selectivity of needle and fine-wire electrodes depends on the size of the recording surface. The concentric and monopolar needle electrodes used in clinical EMG examinations record primarily from just the tip of the needle. These electrodes sample a region about half a millimeter in radius, which can include muscle fibers from dozens of motor units. The same is true for fine-wire electrodes with a half-millimeter-long recording surface. With these electrodes it is usually possible to sort out individual MUAP trains from signals recorded at up to about a third of maximum strength in many muscles. More selective electrodes with smaller recording surfaces have been developed for detecting individual MUAP trains from stronger contractions.

Surface electrodes have the advantage that they are completely non-invasive, but the limitation that they can only sample superficial muscles. Since surface electrodes are far away from the muscle fibers, the MUAPs they record are small in amplitude and tend to all look alike. Electrode arrays are often necessary in order to obtain decomposable signals.