The 24th century Starfleet personal communicator is attached to crew members' uniforms on the left side of the chest. It is an indispensable piece of basic equipment, and is worn at all times.
The communicator is made of a crystalline composite of silicon, beryllium, carbon 70, and gold, and has a protective casing made of micromilled duranium coated with gold and silver alloys. For aesthetic purposes, it is fashioned in the shape of the Starfleet emblem. Underneath the duranium casing there is a a set of complex components powered by a sarium krellide crystal that supplies enough power for two week's use. When the crystal is almost exhausted it produces an audible oscillation, and power can be restored by induction recharging.
The main component in the communicator is the subspace transceiver assembly (STA), which incorporates an analog-to-digital voice encoder and a low power subspace field emitter. The communicator's STA does not make use of the wide range of data input channels that are so important in PADDs and tricorders. Because of the STA's small size and low power levels, it can only generate a relatively weak subspace field. Transmissions between personal communicators have a range of approximately 500 kilometers, and this can be affected by local factors such as EM fields.
The ship's short-range transceivers are used to extend the range of the communicator by picking up its low power signals and sending back high power signals. This makes possible transmissions of up to 60,000km; this is enough to establish ship-to-ground communications, as a vessel generally orbits at distances of 40,000km. The communicator is activated with a simple tap and issues an electronic chip to confirm that it is ready for use. The wearer states the name of the intended recipient, and the communicator establishes the connection. Outgoing transmissions are relayed by a monofilm pickup that is obnded to the inner casing; incoming transmissions are relayed to the communicato's inbuilt audio speaker. The STA converts the user's words into a digital burst that is captured by the short-range subspace or RF transceivers embedded about the ship's hull. The transceivers then coordinate with the onboard optical data network (which controls all intraship and subspace communications) and the main computer com processors to establish a link with the desired location.
The subspace transceivers are linked directly to the transporter systems, and provide personnel locator and transporter lock data. The communications channel is broken with either a voice command or when the communicator itself detects that the discussion has ended. The communicator can, however, remain "hot" - ready to relay follow-up speech without the preliminary tap. In dangerous situations, personnel may maintain an open com link, allowing the ship to monitor their conversation at all times. The communicator has very few user controls, and as a result the starship must adjust for any interference independently. Personal communicators are not necessary on board vessels equipped with an intraship com system, which automatically detects verbal messages without the need for an additional external device.
Starfleet procedure dictates that all communications must be sent in encrypted form. The communicator's encryption circuit assembly computes the encryption algorithms prior to transmission. The encryption algorithm comes from, and is randomly changed by Starfleet Command for all Starfleet communications. The communicator's dermal sensor can be programmed to respond t only a specific user's bioelectrical field and temperature profile, preventing unauthorized personnel from using the communicator.
The communicator can be set to transmit a homing signal during emergencies; once activated, it becomes a subspace beacon. If the communicator's casing is destroyed, the homing signal is automatically triggered to help rescuers search for injured personnel.