|
PREFACE
TABLE OF CONTENTS Chapter 4.8 - Power Strategy
4.8 POWER STRATEGYCommunications systems are typically powered by –48 V DC power supply. This power is then down- (and/or up-) converted to 5, 3.2, or other voltages, as electronic and optical components require. However, because the reliability of system also depends on supplied power, the powering plan is redundant (duplex), that is, two independent –48 V feeders supply power to the system, one in active mode and the other in standby mode, but one supplies power to the shelf. Power sensors detect the power status (or "health") of each feeder. When the sensors detect that the supplied voltage is below a threshold voltage (typically at –39.25 ± 0.25 V and for longer than 100 msec), they cause a feeder switch in a manner that generates no power transients that may cause a disruptive effect on transmission or excessive electromagnetic interference (EMI). This is resolved easily with power filters per feeder. Similarly, the sensors should not cause a switch to a restored feeder unless the (feeder's) voltage is greater by 0.25 V than the voltage it caused a switch to stand by or shut down. In addition, there must be overvoltage protection on both active and standby feeders. This is resolved with circuit breakers. Depending on the circuit breaker distribution strategy throughout the system, the breakers may be slow-blow and they should be able to handle the maximum allowable voltage and current they are designed for indefinitely. In one distribution, there may be a main feeder slow blow (60 ms) breaker (at the power feed to the system), a shelf slow blow (50 ms) breaker (at the power feed to the shelf), and a fast blow breaker on the unit. Other configurations depend on the size and complexity of the system; for example, small systems (shelf-size) may have a single breaker. A key design in the power detection strategy is not to power the sensors by the power feeder they monitor. Another key design is to allocate the same pins across the backplane should be assigned for power and ground and they should be isolated from low-voltage signals. In addition, backplane pins must be sequenced so that power and ground are applied first and then the signals. When the active feeder fails (because of under- or overvoltage) and power is switched to the standby feeder, an alarm signal should be generated to alert the system administrator (craft and software). It also is desirable that technical personnel be able to see which of the two feeders supplies power; this visual indication is achieved with LEDs on the front panel of the system. All critical components on the power plant (fuses, sensors, power switching, etc.) must be monitored and cause a message to be sent to the shelf/system controller. Finally, it is important that the ground architecture of the system be robust to avoid ground loops, which may increase EMI. To also avoid electrostatic discharge (ESD), the front panels should be supplied with ground connectors that the personnel can use when handling circuit packs in the system. |
