Optical transmitter or transmission unit in optical transmitter/receiver provided on opto-electric hybrid board

1 . An optical transmitter or a transmission unit in an optical transmitter/receiver provided on an opto-electric hybrid board comprising: a semiconductor laser for emitting laser light by use of plural channels; optical waveguides, coupled respectively and optically to the semiconductor laser, for allowing pieces of the laser light for the respective channels to propagate through the optical waveguides as pieces of input light; optical modulators for generating optical signals by modulating the pieces of input light; and optical signal outputting parts, respectively coupled to the optical modulators, for outputting the optical signals propagated through the optical modulators to the outside; wherein the optical transmitter or the transmission unit in the optical transmitter/receiver characterized in that, on a plane of the opto-electric hybrid board, the semiconductor laser being placed on a side of the optical signal outputting parts opposite to another side of the optical signal outputting parts where the optical modulators are placed. 2 . The optical transmitter or the transmission unit in the optical transmitter/receiver according to claim 1 , wherein it is characterized in that each of the optical signal outputting parts comprises a grating coupler for diffracting the propagated optical signal, and an optical pin optically coupled to the grating coupler and installed to stand with a desired angle with respect to a plane of the opto-electric hybrid board for outputting the optical signal to the outside. 3 . The optical transmitter or the transmission unit in the optical transmitter/receiver according to claim 1 further comprising optical branching units, wherein each of the optical branching units divides the laser light into two or more pieces of input light, and the modulators are respectively coupled to two or more optical output terminals provided to the optical branching unit. 4 . The optical transmitter or the transmission unit in the optical transmitter/receiver according to claim 3 , wherein it is characterized in that the semiconductor laser comprises m channels (m is an integer that is equal to or more than 1), the optical waveguides comprise first to m-th optical waveguides, and the optical branching units comprise first to m-th optical branching units, each of the first to m-th optical branching units divides the laser light into n pieces of input light (n is any integer that is equal to or more than 2), and the n pieces of input light are coupled via the optical output terminals to first to n-th optical modulators, and a k-th optical waveguide (k is any integer that is equal to 1 or m, or between 1 and m) is coupled to a k-th optical branching unit through a space between an n-th optical modulator coupled to a (k−1)th optical branching unit and a first optical modulator coupled to the k-th optical branching unit, or a space between an n-th optical modulator coupled to the k-th optical branching unit and a first optical modulator coupled to a (k+1)th optical branching unit, for making the connection length of each of the plural optical waveguides to be equal. 5 . The optical transmitter or the transmission unit in the optical transmitter/receiver according to claim 3 , wherein it is characterized in that each of the optical branching units comprises plural two-branch optical couplers or plural three-branch optical couplers arranged in multiple stages for dividing the laser light into any number of pieces of input light. 6 . The optical transmitter or the transmission unit in the optical transmitter/receiver according to claim 1 , wherein it is characterized in that each of the optical waveguides is arranged as a curved waveguide having a curved part; and the optical waveguide extends from the semiconductor laser along a direction orthogonal to a linear direction toward the optical signal outputting parts corresponding to the optical waveguide and, at the curved part positioned at a predetermined distance from the semiconductor laser, curves 90 degrees in a linear direction toward the optical signal outputting parts.