A Novel 3-D microwave holographic imaging algorithm compatible with both single-probe and dual-probe scanning setups is proposed for imaging dielectric targets. In some cases, even with only one probe antenna, the quality of the images reconstructed using the proposed algorithm is comparable or even superior to those using dual-probe-based methods. The proposed algorithms can be divided into four parts. First, starting from the open-circuit voltage of an antenna, the proposed algorithm compensates for both transmitting and receiving properties of the probe antenna, leading to least squares problems to be determined. However, the problem tends to be ill-conditioned in the single-probe setup (irrelevant to the dual-probe one). Second, an auxiliary equation based on lossless condition of an unknown target is thus derived and exploited to effectively improve the numerical stability. Third, to accurately locate the unknown target in range direction, a phase compensation method that requires only phase correction to the associated entries of the kernel matrices is proposed based on a simple ray model. Last but not least, considering both a finite size of a scanning aperture and beamwidth of the probe antenna, a numerical low-pass filter in the spatial-frequency domain is devised to effectively locate the worth-solving area and thus reduce computational time substantially. For verification, a series of images reconstructed from the simulated and measured scattering data using the proposed algorithm are presented. Thanks to the enhanced image quality, the geometry, location, and dielectric constant of the target can readily be retrieved. The range and cross-range resolutions achieved are about /10 and /4,