Myocardial analysis apparatus and myocardial excitation detection apparatus

What is claimed is: 1. A method of a myocardial analysis apparatus visualizing a state of excitation in a myocardium of a subject, the method comprising: acquiring intracardiac electrocardiograms of the subject, the intracardiac electrocardiograms being recorded by a recording unit having a plurality of electrodes; performing a computation for completing and visualizing the state of excitation in the myocardium of the subject based on the intracardiac electrocardiograms; and outputting the state of excitation in the myocardium of the subject based on an output of the performing the computation, wherein the performing the computation comprises: with respect to each of the plurality of intracardiac electrocardiograms that are recorded by the plurality of electrodes of the recording unit, generating a pseudo action potential waveform; performing a correction for equalizing amplitudes of unit waveforms contained in the action potential waveforms; with respect to each of the action potential waveforms that are corrected, generating a shifted waveform that is different in time phase from the action potential waveform; and preparing a phase portrait based on each of the action potential waveforms that are corrected, and the shifted waveform corresponding to the action potential waveform, and generating visualized data indicating the state of excitation in the myocardium of the subject, based on the phase portraits, and wherein the outputting comprises outputting a change of the state of excitation in the myocardium of the subject based on the visualized data. 2. The method according to claim 1 , wherein the shifted waveform is a waveform which is different in time phase by N+(¼) of a mean action potential duration from the action potential waveform, and N is 0 or a positive integer. 3. The method according to claim 1 , further comprising: when the pseudo action potential waveform is to be generated, detecting a unit waveform in the pseudo action potential waveform by using a shortest cycle length which is obtained by adding a shortest diastolic interval and shortest action potential duration in an ideal model of a unit waveform contained in the action potential waveform of the myocardium. 4. The method according to claim 1 , wherein performing the correction comprises performing the correction based on relationships between a diastolic interval and action potential duration in an ideal model of a unit waveform contained in the action potential waveform of the myocardium. 5. The method according to claim 1 , wherein performing the computation comprises: defining a virtual electrode at a position which is in the myocardium of the subject, and in which the electrodes of the recording unit are not placed, and interpolating a pseudo action potential waveform with respect to the virtual electrode, based on the action potential waveforms generated with respect to electrodes surrounding the virtual electrode; and interpolating the pseudo action potential waveform and the shifted waveform by using a spatial interpolation technique with respect to positions which are in the myocardium of the subject, and in which the electrodes of the recording unit and the virtual electrode are not placed. 6. The method according to claim 1 , further comprising: when visualized data indicating the state of excitation in the myocardium of the subject are to be generated based on the phase portrait, in a unit waveform contained in the action potential waveform, defining a portion where the action potential exceeds a center of the phase portrait with a warm color, and a portion where the action potential is lower than the center with a cool color. 7. The method according to claim 1 , wherein performing the computation comprises: extracting a first grid set that is configured by a predetermined number of grids, from the visualized data, and detecting a center of the first grid set as a phase singularity in a case where a total of color differences between adjacent grids in the first grid set is equal to or larger than a predetermined value, and all of predetermined colors are contained in a second grid set that is centered on the first grid set, and that is configured by grids a number of which is larger than a number of the grids in the first grid set. 8. A method of a myocardial analysis apparatus visualizing a state of excitation in a myocardium of a subject, the method comprising: acquiring intracardiac electrocardiograms of the subject, the intracardiac electrocardiograms being recorded by a recording unit having a plurality of electrodes; performing a computation for completing and visualizing the state of excitation in a myocardium of the subject based on the intracardiac electrocardiograms; outputting the state of excitation in the myocardium of the subject based on an output of the performing the computation; and storing a plurality of action potential unit waveforms that are previously generated by computer simulation, wherein the performing the computation comprises: with respect to each of the plurality of intracardiac electrocardiograms that are recorded by the plurality of electrodes of the recording unit, generating a pseudo action potential waveform by using the action potential unit waveforms; with respect to each of the action potential waveforms, generating a shifted waveform that is different in time phase from the action potential waveform; and preparing a phase portrait based on each of the action potential waveforms and the shifted waveform corresponding to the action potential waveform, and generating visualized data indicating the state of excitation in the myocardium of the subject, based on the phase portraits, and outputting a change of the state of excitation in the myocardium of the subject based on the visualized data. 9. The method according to claim 8 , wherein the shifted waveform is a waveform which is different in time phase by N+(¼) of a mean action potential duration from the action potential waveform, and N is 0 or a positive integer. 10. The method according to claim 8 , wherein performing the computation comprises: detecting time intervals between the unit waveforms contained in the intracardiac electrocardiogram, and sequentially selecting the action potential unit waveforms which are to be used in the production of the pseudo action potential waveform, based on relationships between a diastolic interval and action potential duration in an ideal model of a unit waveform contained in the action potential waveform of the myocardium. 11. The method according to claim 8 , wherein performing the computation comprises: defining a virtual electrode at a position which is in the myocardium of the subject, and in which the electrodes of the recording unit are not placed, and interpolating a pseudo action potential waveform with respect to the virtual electrode, based on the action potential waveforms generated with respect to electrodes surrounding the virtual electrode; and interpolating the pseudo action potential waveform and the shifted waveform by using a spatial interpolation technique with respect to positions which are in the myocardium of the subject, and in which the electrodes of the recording unit and the virtual electrode are not placed. 12. The method according to claim 8 , further comprising: when visualized data indicating the state of excitation in the myocardium of the subject are to be generated based on the phase portrait, in an action potential unit waveforms contained in the action potential waveform, defining a portion where the action potential exceeds a center of the phase portrait with a warm color, and a portion where th