It becomes difficult to locate a new infrastructure on a stiff and hard ground in urban areas throughout the world. Renovation or retrofit of old infrastructures should often be carried out in the close proximity of the existing structures. Good-quality ground for constructions is becoming a precious resource to be left for the next generation. Due to these reasons and environmental restrictions on the public works, ground improvement is becoming an essential part of the infrastructure development projects both in the developed and developing countries. This situation is especially pronounced in Japan, where many construction projects must locate on soft alluvial clay grounds, artificial lands reclaimed with soft dredged soils, highly organic soils and so on. These ground conditions would pose serious problems of large ground settlement and/or instability of structures. Apart from clayey or highly organic soils, loose sand deposits under water table would cause a serious problem of liquefaction under seismic condition. When these problems are anticipated not to assure the performance and function of superstructure, the ground is called a ‘soft ground’ and needs to be improved and reinforced. Required performance and function of the ground are, however, different for different structures. It is not appropriate to define a ‘soft ground’ by its geotechnical characteristics alone but by incorporating the size, type, function and importance of superstructure and construction period. Only if the type of superstructure is specified, it is possible to define the ‘soft ground.’ Table 1.1 provides rough idea of the ‘soft ground’ for several types of structure in terms of water content, unconfined compressive strength, SPT N-value, ground thickness and bearing capacity (The Japanese Society of Soil Mechanics and Foundation Engineering, 1986).

If superstructure to be constructed would be unstable under given conditions of external loads and of original ground, or if expected deformation during and/or after construction would exceed an allowable value from the viewpoint of expected function of superstructure, necessary countermeasures must be undertaken. The following four approaches can be applied: (a) changing type of superstructure and/or type of its foundation, (b) replacing soft soil by better quality soil, (c) improving properties of soft soil, and (d) introducing reinforcing material into soft soil. ‘Ground improvement’ covers (b), (c) and (d) above, and can be defined as any countermeasures given to soft soil in order to attain the successful performance of superstructure if otherwise unattainable. The ground improvement techniques can be classified, based on their working principles, into replacement, densification, consolidation/dewatering, grouting, admixture stabilization, thermal stabilization, reinforcement and miscellaneous. These techniques have been introduced to or originally developed in Japan during the past decades.

The deep mixing method, one of the admixture stabilization techniques, was developed in Japan and put into practice in the middle of the 1970s. Since then, the wet and dry methods have been applied to many improvement purposes and a lot of research studies and case histories have been accumulated (Kitazume and Terashi, 2013).