Using intraslab earthquakes shallower than 150 km in the southernmost Ryukyu subduction zone, previous studies in Taiwan found the waveguide effect that typically shows a low-frequency (<2Hz) first P arrival followed by sustained high-frequency (3–10 Hz) wave trains. Recently occurred deeper events at depth 150-300 km allow us to better quantify the properties of those seismic waves traveling in the subduction zone. In this study, we aim to systematically scan through the local broadband waveforms of the intermediate depth earthquakes with M>4 between 1997 and 2016. Events are classified based on the waveform characteristics and their frequency contents. To detect events with similar properties, we applied sliding-window cross-correlation (SCC) using three components of P waveform data simultaneously for a set of stations. We then sorted the events into families based on correlation coefficients (cc) and inter-distances between waveform pairs. The events within a family likely came from the same source region with similar rupture, as such their paths to a particular receiver should produce similar waveforms. In our results, although several events present enough similarities (cc≥0.6 threshold) and can be grouped as a family, we did not observe closely resembled pairs (cc≥0.9), implying no “repeating” behavior for those intermediate intraslab events. One important property is the frequency content of the arrivals that may be related to the speed of structure traveled. We have developed a work scheme to determine the delayed time of higher-frequency energy using spectrogram and spectral ratios. A set of 6 events show clear continuous dispersion at frequency range between 0.5 and 6 Hz where arrival time smoothly increases by about 2 s in total. Another type of dispersive waveforms appeared as two distinct arrivals: low frequency and then high-frequency energy, separated by around 1 s. The latter case has been reported in the previous study for shallower event and it was interpreted as effect from low-velocity layer or heterogeneity of the subducted slab. On the other hand, the continuous dispersion is a new feature observed by our study, which may infer a thinner layer and/or longer propagation for some kind of reflecting waves to develop such interference. The simulation indicates that the low-velocity waveguide should be thinner than 10 km and the propagation distances within the layer should be longer than 100 km, assuming a P-wave drop of about 5-7%.