MCARC Repeater – MHz Design & Operation A repeater is an automatically controlled transmitter and receiver that simultaneously transmits what the receiver hears.

Components of a Repeater System Antenna Feedline Duplexer Receiver Transmitter Controller

Basic Repeater Operation Offset To use a repeater a user station must use a different transmit frequency than receive frequency.The difference between receive and transmit frequencies is called the Offset. Types of Access (Squelch Operation) Carrier CTCSS (PL, Tone), DTMF Digital (DCS)

Squelch Operation Carrier Detects white noise. Stronger signals have less noise. Usually in the 4 KHz to 5 KHz range. CTCSS (PL, Tone, …) Detects subaudible tone (67Hz to 250 Hz) transmitted by user Digital (DCS) Subaudible (134 Baud) continuous digital stream DTMF (Touch-Tone) Not often used, but most users have ability to send DTMF

Multiple Receivers & Voting Extends coverage area of repeater Good handheld coverage near receive sites. Voter determines which receiver has best signal Our system uses signal/noise ratio to determine best signal All receivers should be matched in level, bandwidth, and linearity. Our system uses flat, wide bandwidth receivers. Remote receive sites linked back to the main controller using low power 440 MHz transmitters. Our system uses flat, wide bandwidth link transmitters.

Multiple Receivers & Voting Equal audio characteristics ensures seamless voting System may vote many times per second on a fluctuating signal, but is not detectable listening to the voted output. Fast squelch and response times necessary to prevent audio “holes” during signal dropouts. Our system has less than 1 ms response time Each remote site has a controller to manage timers and squelch control. Microchip PIC microprocessors are used for controller and CTCSS detection.

Receive Site Control Squelch Mode: Carrier or CTCSS “AND” and “OR” type CTCSS mode Enhanced (loose) carrier squelch Temporary Modes for Special Conditions DTMF Control of all functions Unique CTCSS decoder using DSP technique Software detection using Goertzel algorithm s(n) = x(n) + 2cos(2πω)s(n − 1) − s(n − 2) Cheap hardware, excellent performance Overall remote receive site performance indistinguishable from a local receiver – virtually “transparent”.

The Receivers London Hamtronics R-301 2M VHF Receiver Hamtronics R-304 UHF Link Receivers Receivers are synthesized (no crystals needed) Unsquelched, discriminator audio from the receiver – no de-emphasis Overall frequency response flat from 40 Hz to 5 KHz Linear from 0 to 8 KHz deviation

The Voter Hardware The small perf-board circuit is the CW-Beep board that identifies which receiver is voted after each transmission.

Voter and Receivers The 4 receivers and voter combine to act like a single receiver input into the repeater.

Hamtronics Receive Sites West Jefferson & Plain City Control BoardR-301 VHF ReceiverT-304 UHF Link Transmitter Receiver and Transmitter are synthesized (no crystals needed) Unsquelched, discriminator audio from the receiver – no de-emphasis Direct FM modulation of the 2W transmiter – no pre-emphasis or limiting Overall frequency response flat from 40 Hz to 5 KHz Linear from 0 to 8 KHz deviation

Hamtronics Receive Sites West Jefferson & Plain City West Jefferson Site 9.5 Miles link distance to London Plain City Site 17.7 Miles link distance to London

Hamtronics Receive Sites Frequency Response

Hamtronics Receive Sites Linearity

Motorola / GE Receive Site Mt. Sterling Motorola Micor 30 A Power Supply Motorola Micor VHF Receiver GE Mastr-II UHF Transmitter Receiver and Transmitter use crystal channel elements. Unsquelched, discriminator audio from the receiver – no de-emphasis Direct FM modulation of the 10W transmiter – no pre-emphasis or limiting Overall frequency response flat from 40 Hz to 8 KHz Linear from 0 to 6 KHz deviation Mt. Sterling Site – 15.8 Miles link distance to London

Motorola / GE Receive Site Frequency Response

Receive Site Matching Frequency Response

Receive Site Matching Linearity

Transmitter / Control Site London Astron RS-35A Power Supply (Not visible – 12V/13AH Battery) Hamtronics REP-200 Controller (Includes T Watt Exciter and LPA Watt Amplifier) VoCom 100W Repeater-Duty Amplifier Voter and Receivers Assembly

Duplexer Isolation 85 dB typical (300,000,000:1 power ratio) Only 0.4% frequency difference between XMIT & RCV frequency – VERY CLOSE! Cable leakage, imperfect tuning, and inadequate shielding can easily reduce isolation by 30dB Insertion Loss 1.5 dB typical (100 Watts in, 71 Watts out) Calculation of Required Isolation: Receiver sensitivity 0.1 uV (-107 dBm), with dynamic range of 75 dB (-32 dBm, 5000μV max receiver input) Transmitter 100W (+50 dBm) - Duplexer isolation 85 dB = 0.3μW (-35dBm, 4000μV) into receiver. Very Expensive - $1200 and up

Dual Isolator London Ferrite Isolators prevent reflected power from damaging the transmitter, and present a constant 50 Ω load to the transmitter regardless of the actual load conditions. Any reflected power is dissipated into the attached dummy loads. The isolator is placed between the transmitter output and the duplexer. It also prevents other transmitters energy that may be at the repeater site from entering our transmitter’s output stage, which could create intermod and other spurious signals. Very expensive - $500 to $1500 typical

Repeater Antenna London Very durable antenna – preferred by many repeater operators. Also very expensive, about $700

Future Upgrades New exciter and 25W amplifier for the main transmitter in London. Crystal controlled, low phase noise for less desense of local receiver. (under construction) New antenna and feedline in London (awaiting installation) New link receive antenna for West Jeff link in London (awaiting installation) Add cooling fan to Astron power supply in London 82.5 Hz notch filter and CTCSS regeneration at the main transmitter. (enables remote linking capability) Other suggestions???