A concept is introduced for initiating the design study of a special class of tokamak,which has a magnetic confinement configuration intermediate between contemporary advanced tokamak and the recently established spherical torus (ST,also well known by the name “spherical tokamak”).The leading design parameter in the present proposal is a dimensionless geometrical parameter, the machine aspect ratio A=R 0/a 0= 2.0,where the parameters a 0 and R 0 denote,respectively,the plasma (equatorial) minor radius and the plasma major radius.The aim of this choice is to technologically and experimentally go beyond the aspect ratio frontier (R 0/a 0≈2.5) of present day tokamaks and enter a broad unexplored domain existing on the (a 0,R 0) parameter space in current international tokamak database,between the data region already moderately well covered by the advanced conventional tokamaks and the data region planned to be covered by STs.Plasma minor radius a 0 has been chosen to be the second basic design parameter, and consequently,the plasma major radius R 0 is regarded as a dependent design parameter.In the present concept,a nominal plasma minor radius a 0=1.2m is adopted to be the principal design value,and smaller values of a 0 can be used for auxiliary design purposes,to establish extensive database linkage with existing tokamaks.Plasma minor radius can also be adjusted by mechanical and/or electromagnetic means to smaller values during experiments,for making suitable data linkages to existing machines with higher aspect ratios and smaller plasma minor radii.The basic design parameters proposed enable the adaptation of several confinement techniques recently developed by STs,and thereby a specially arranged central bore region inside the envisioned tokamak torus,with retrieved space in the direction of plasma minor radius,will be available for technological adjustments and maneuverings to facilitate implementation of engineering instrumentation and real time high field side radiation and particle diagnostics,especially for high field side edge physics and plasma surface interaction studies. A concept is introduced for initiating the design study of a special class of tokamak, which has a magnetic confinement configuration intermediate between contemporary advanced tokamak and the recently established spherical torus (ST, also well known by the name “” spherical tokamak "). The leading design parameter in the present proposal is a dimensionless geometrical parameter, the machine aspect ratio A = R 0 / a 0 = 2.0, where the parameters  a 0 and R 0 denote, respectively, the plasma (equatorial) minor radius and the plasma major radius. The aim of this choice is to technologically and experimentally go beyond the aspect ratio frontier ( R 0 / a 0 ≈ 2.5)  of present day tokamaks and enter a broad unexplored domain existing on the  (a 0, R 0)  parameter space in current international tokamak database, the data region already moderately well covered by the advanced conventional tokamaks and the data region planned to be covered by STs.Plasma minor radius  a 0 has been chosen to be the second basic design parameter, and therefore, the plasma major radius  R 0 is found as a dependent design parameter. In the present concept, a nominal plasma minor radius  a 0 = 1.2m is adopted to be the principal design value, and smaller values ​​of  a 0 can be used for auxiliary design purposes, to establish extensive database linkage with existing tokamaks. Plasma minor radius can also be adjusted by mechanical and / or electromagnetic means to be smaller values ​​during experiments, for making suitable data linkages to existing machines with higher aspect ratios and smaller plasma minor radii. The basic design parameters proposed enable the adaptation of adaptation number of confinement techniques recently developed by STs, and thus a specially arranged central bore region inside the envisioned tokamak torus, with retrieved space in the direction of plasma minor radius, will be available for technological adjustments and maneuverings to facilitate impl ementation of engineering instrumentation and real time high field side radiation and particle diagnostics, especially for high field side edge physics and plasma surface interaction studies.