Add to ORKGMany feedback loops are used at the Stanford Linear Collider (SLC) to control the orbit and energy of particle beams. Problems with corrector magnet slew rates, actuator calibrations, and computation of the beam transport matrix between loops have resulted in operation of many SLC feedback loops at lower than design gain. The response of various feedback loops to these errors is measured and analyzed in an attempt to improve performance
An Interaction Point Collision Feedback System is necessary to achieve design luminosity at the futu...
To fully characterize the luminosity performance of a linear collider, it is important to simulate t...
Amajor upgrade to the SLC final focus was installed in 1994 to eliminate the dominant third-order ab...
Beam-based feedback systems were a key element in the successful operation of the Stanford Linear Co...
Feedback systems are essential for stable operation of a linear collider, providing a cost-effective...
Feedback systems are essential for stable operation of a linear collider, providing a cost-effective...
A fast feedback system provides beam stabilization for the SLC. As the SLC is in some sense a protot...
The tolerances on the beams as they collide at the interaction point of the TESLA linear collider ar...
The performance of high energy linear colliders depends critically on the stability with which they ...
The design luminosity for the future linear colliders is very demanding and challenging. Beam-based ...
Beam-based feedback systems play an essential role in the operation of high energy electron-positron...
Extensive beam-based feedback systems are planned as an integral part of the Next Linear Collider (N...
The NLC linac train-by-train feedback system is designed to stabilize the beam trajectory, but is al...
The Stanford Linear Collider (SLC) uses scvcral very fast thyratron pulsers to drive kicker magnets....
In order to reduce the influence of magnet vibrations which can cause luminosity reduction in the TE...
An Interaction Point Collision Feedback System is necessary to achieve design luminosity at the futu...
To fully characterize the luminosity performance of a linear collider, it is important to simulate t...
Amajor upgrade to the SLC final focus was installed in 1994 to eliminate the dominant third-order ab...
Beam-based feedback systems were a key element in the successful operation of the Stanford Linear Co...
Feedback systems are essential for stable operation of a linear collider, providing a cost-effective...
Feedback systems are essential for stable operation of a linear collider, providing a cost-effective...
A fast feedback system provides beam stabilization for the SLC. As the SLC is in some sense a protot...
The tolerances on the beams as they collide at the interaction point of the TESLA linear collider ar...
The performance of high energy linear colliders depends critically on the stability with which they ...
The design luminosity for the future linear colliders is very demanding and challenging. Beam-based ...
Beam-based feedback systems play an essential role in the operation of high energy electron-positron...
Extensive beam-based feedback systems are planned as an integral part of the Next Linear Collider (N...
The NLC linac train-by-train feedback system is designed to stabilize the beam trajectory, but is al...
The Stanford Linear Collider (SLC) uses scvcral very fast thyratron pulsers to drive kicker magnets....
In order to reduce the influence of magnet vibrations which can cause luminosity reduction in the TE...
An Interaction Point Collision Feedback System is necessary to achieve design luminosity at the futu...
To fully characterize the luminosity performance of a linear collider, it is important to simulate t...
Amajor upgrade to the SLC final focus was installed in 1994 to eliminate the dominant third-order ab...