There are two ways to cause the redirection of the beam from the antenna's midline. The first is referred to as a
rotated feed. As its name suggests, a feed horn is set just off the parabolic focal point which causes the energy to focus slightly off the antenna midline. The feed is then rotated around the focal point of the paraboloid to produce the conical rotation. The other system is a
nutated feed. A nutated feed offsets the antenna at an angle to a fixed feed horn, and then rotates the antenna. A variation of a nutated feed makes the feed move in a small circle, rapidly and continuously changing the pointing direction of the beam. In this latter type, neither the feed nor the antenna revolves around the pointing axis of the antenna; only the pointing direction changes, tracing out a narrow cone. The primary difference between the two basic schemes is in polarization. As the feed horn in the rotated process spins, the polarization changes with the rotation and will thus be 90 degrees off in polarization when the feed is 90 degrees off its initial axis. As the feed horn is fixed in nutated feeds, no polarization changes occur. Most early systems used a rotated feed, due to its mechanical simplicity, but later systems often used nutated feeds in order to use the polarization information. In the U.S. Navy Mk. 25 gun fire control radar, spiral scan mode aided
target acquisition. Basically conical scan (of the non-revolving nutating feed type), the size of the scan cone cyclically increased and decreased roughly twice a second. The scanned area was several degrees, in all. (Once the target was acquired, the operator switched to conical scan for tracking.) Since the lobe is being rotated around the midline of the antenna, conical scanning is only really appropriate for antennas with a circular cross section. This was the case for the Würzburg, which operated in the
microwave region. Most other forces used much longer-wavelength radars that would require
paraboloid antennas of truly enormous size, and instead used a "bedspring" arrangement of many small
dipole antennas arranged in front of a passive reflector. To arrange conical scanning on such a system would require all of the dipoles to be moved, an impractical solution. For this reason the
US Army simply abandoned their early gun laying radar, the
SCR-268. This was not particularly annoying, given that they were in the process of introducing their own microwave radar in the aftermath of the
Tizard Mission introducing, among other things, the
cavity magnetron, which enabled centimetric-wavelength radio signal generation orders of magnitude stronger than the then-current
klystron tube. In the resulting
SCR-584, the
MIT Radiation Laboratory introduced automatic tracking. Automatic guidance for the antenna, and thus any slaved guns or weapons, can be added to a conical scan radar without too much trouble. The control system has to steer the antenna such that a constant amplitude return is received from the target. Unfortunately there are a number of factors that can dramatically change the reflected signal. For instance, changes in the target aircraft's direction can present different portions of the
fuselage to the antenna, and dramatically change the amount of signal being returned. In these cases, a conical scan radar might interpret this change in strength as a change in position. For instance, if the aircraft were to suddenly "brighten" when it was off-axis to the left, the circuitry might interpret this as being off to the right if the change occurs when the lobe is aligned in that direction. This problem can be solved by using two simultaneous overlapping receiver beams leading to the
monopulse radar, so-named because it always compares signal strength from a single pulse against itself, thereby eliminating problems with all but impossibly fast changes in signal strength.
Conical-scan receive-only (COSRO) The introduction of angle deception transponders in WWII led to the introduction of the CORSO technique. In this system, two separate antennas are used, one for transmission and a separate one for reception. Only the receiver is scanning, the transmitter only needs to be pointed in the direction of the target. It is possible to use two separate antenna systems for CORSO, both driven by the error signals from the receiver. However, it is also possible to combine them using two feedhorns in front of a single parabolic reflector, and thereby have a single unit system. In these systems, the receiver has a feedhorn structure that contains a rotating vane. This produces three outputs, the original signal which is used to measure range, and two signals that peak when the vane is either aligned or at right angles to the target, which produce the same error signals that can then be used to drive the aiming motors. Because the vane only effects the signal after reception, there is nothing to indicate to the target that they are being scanned.
Antenna sampling RF receive signals from multiple transmit pulses are combined mathematically to create a vertical and horizontal signal. The vertical signal is created by adding RF samples when the vane/feedhorn is in the up direction and subtracting RF samples when the vane/feedhorn is in the down direction. The horizontal signal is created by adding RF samples when the vane/feedhorn is in the left direction and subtracting RF samples when the vane/feedhorn is in the right direction. This produces a pair of angle error signals used to drive antenna positioning drive motors. ==Jamming==