The negative exponent function controller is proposed based on the strategy of controlling halo-chaos,and a Kapchinsky-Vladimirsky(K-V) high-current ion beam through an accelerator channel is studied using the particle-in cell procedure(PIC).

A minus paired-dominating function of G is a function of the form f:V→{-1,0,1} such that f(v)=1 for any vertex v ∈ D,f(v)≤0 for any vertex v ∈ V-D,and f(N[v])≥1 for any vertex v ∈ V.

Let DV be any paired-dominating set of G=(V, E), a minus paired-dominating function of G is a function of the form f:V→{-1,0,1} such that f(v)=1 for any vertex v∈D,f(v)≤0 for any vertex v∈V-D,and f(N[v])≥1 for any vertex v∈V.

Aiming at the influence of the gross error to the estimated value of the parameter, when determining the undetermined parameters in the negative exponential function using weighted least square method, the paper presents the robust solution of the undetermined parameters.

Beam halo-chaos for five different initial ion distributions is effectively controlled by a logarithm-function controller based on the variable.

The effect on the beam radius due to the change of the filling factor for K-V distribution was studied under logarithm-function controller and was compared with the result of the delayed feedback controller.

Based on those, the impact on beam halo-chaos control’s effect due to the change of filling factor for K-V distribution was studied under the logarithm-function controller by selecting ion numbers ratio as controlling variable and selecting root-mean-square radius as controlling variable, and was compared with t.