Beam loading analysis and control in standing wave cavities

TL;DR

This paper analyzes beam loading effects in standing wave RF cavities using an equivalent circuit model, deriving analytical solutions and proposing control methods to mitigate beam-induced errors, validated through simulations.

Contribution

It introduces a comprehensive analytical approach for wideband cavities and proposes effective feedforward and feedback control strategies for beam loading compensation.

Findings

Analytical expressions for beam-induced cavity voltages are derived.

Control methods effectively reduce beam loading effects in simulations.

The approach applies to both narrowband and wideband cavities, including circular accelerators.

Abstract

The interaction between a particle beam and the accelerating mode of a radiofrequency (RF) cavity cause beam loading, representing the beam-induced cavity fields. Beam loading leads to amplitude and phase errors in the cavity fields and reduces the beam quality, especially in accelerators with large beam currents, wideband RF cavities, or circular machines where particles stay for multiple turns. Insight into the principle of beam loading is helpful to understand the beam measurement results and propose efficient compensation methods in low-level RF systems. In this work, the beam loading effects are studied with the equivalent circuit model of standing wave cavities. Analytical results of beam-induced cavity voltages are derived for both a single bunch and a bunch train using the phasor Laplace transform method. The results are general for wideband cavities with a bandwidth that may cover multiple harmonics of the bunch repetition frequency. Based on the analysis, control methods in form of feedforward and feedback are proposed to compensate for the beam loading. Simulation studies are carried out to validate these control methods with a cavity simulator including both the RF drive and beam loading. The analysis and control methods are also applicable to the beam in a circular accelerator with coupled-bunch instabilities, which are discussed in the last part of this paper. This work also acts as a supplementary material to another work of the author, in which the beam loading effects are analyzed only for narrow-band cavities with only one beam harmonic appearing in the cavity bandwidth.