H E control system you use for your robot must fulfill several require-
                                    ments. It should be reliable and reasonably immune to interference. It should have
                                    at least enough range to communicate to your robot in the far corner of the
                                    arena—and preferably much more to be safe. The receiving system should be
                                    small and able to withstand a lot of vibration and shock. It should be able to com-
                                    mand multiple systems on your robot simultaneously. It should be capable of varied
                                    degrees of control so that your robot does not have to drive at full speed all the
                                    time. And, finally, it should be available as a reasonably inexpensive off-the-shelf,
                                    solution so that you do not have to spend more time engineering the radio control
                                    (R/C) gear than the rest of the robot.
                                      In the early days of robotic competition, robot builders attempted to use every-
                                    thing from garage-door–opener radios modified for multiple command channels
                                    to radio gear sending commands encoded in audio tones, infrared remote con-
                                    trols, tether-line controls, and networked computers running over wireless modem
                                    links. The most effective technology turned out to be hobby radio control (R/C)
                                    gear, the relatively low cost, off-the-shelf R/Cs intended for use in model cars and
                                    planes. Today, nearly every robot in major competitions uses some form of com-
                                    mercial hobby R/C, and competitions have based their R/C rules around this stan-
                                    dard control system.


                              T raditional R/C Controls


                                    All R/C systems, whether AM or FM radio systems or high-end computerized trans-
                                    mitter and receiver sets (which are all discussed later in this chapter), use essentially
                                    the same electrical signals to transmit control information from the radio receiver to
                                    the various remotely controlled servos and electronic motor controllers. See Figure
                                    8-1. A three-wire cable runs from the radio receiver to each speed controller and
                                    servo in the robot. One wire provides about 5 volts of power to run the servos. A
                                    second wire is a ground reference and power return line. The third line carries the
                                    encoded 1- to 2-millisecond pulse train signal that commands the motion.
                                      Movement commands are encoded with a pulse position modulation system
                                    (some people call this “pulse-width modulation”; Chapter 7 explains the difference


               158