Laser device having semiconductor laser array stacks

The invention claimed is: 1. A laser device comprising: N semiconductor laser array stacks (N is an integer of two or more) that are configured to include a plurality of semiconductor laser arrays each of which emits laser lights from two or more light emission regions being arranged in a predetermined direction while having emission directions aligned and which are stacked in a stacking direction intersecting the predetermined direction and the emission direction, and output the laser lights respectively emitted from the plurality of semiconductor laser arrays as one luminous flux; a first collimation portion that performs collimation in a fast axis direction for the laser lights included in the luminous flux; a prismatic optical system that allows the luminous fluxes which are respectively output from the N semiconductor laser array stacks and pass through the first collimation portion to penetrate therethrough, and shifts an optical axis of the luminous flux in a direction intersecting the optical axis so as to decrease an interval between the luminous fluxes; and an imaging optical system that condenses the luminous fluxes respectively output from the N semiconductor laser array stacks within a plane intersecting a slow axis direction for each luminous flux and deflects the optical axis of each of the luminous fluxes within the plane for each luminous flux, wherein the imaging optical system deflects each of the luminous fluxes so that the N luminous fluxes overlap each other at a predetermined position and generates a focal point of each of the luminous fluxes between the imaging optical system and the predetermined position, wherein the focal points of each of the luminous fluxes are spatially separated. 2. The laser device according to claim 1 , wherein the imaging optical system includes N imaging lenses which condense each of the luminous fluxes respectively output from the N semiconductor laser array stacks for each luminous flux and N deflection optical elements which deflect the optical axes of each of the luminous fluxes for each luminous flux. 3. The laser device according to claim 1 , wherein the N semiconductor laser array stacks are disposed side by side in the stacking direction, and wherein the prismatic optical system shifts the optical axis of the luminous flux in the stacking direction. 4. The laser device according to claim 1 , wherein a first group which includes one or a plurality of the semiconductor laser array stacks and a second group which includes one or the plurality of semiconductor laser array stacks are disposed side by side in a predetermined direction, and wherein the prismatic optical system shifts the optical axis of the luminous flux in the predetermined direction so as to decrease an interval between the luminous flux emitted from the semiconductor laser array stack included in the first group and the luminous flux emitted from the semiconductor laser array stack included in the second group.