The contactless impedance measurement is a kind of technology of image construction to examine biological conductivity by magnetic induction. It is the improvement of application technology at biologic impedance, especially for clinical diagnosis and the tracking the process of disease. The goal of this thesis is to measure the surface impedance of the object. We propose a contactless scheme to measure conductivity. The major scheme includes the sensor, the scanning platform, signal processing system and graphic user interface. This system could estimate the conductivity distribution of the interesting region by contactlessly measuring the coupling field of received coil. The magnetic measurement system could remove the effect of contact impedance. For biologic tissue measurement, the ratio between the primary and secondary components can be up to 10000:1. In order to extract the part of induced current, the primary voltage must be removed from the measurement signal. We use a differential alignment coil to compensate the primary field. The differential alignment sensor could have better effect on the sensitivity. A scanning platform is used to drive the sensor, which extracts the conductivity signal to be calculated and to be reconstructed. In the experiment, three performance indexes are adopted including sensitivity, noise, spatial resolution, to evaluate the proposed coil, and to measure surface impedance of biologic tissues and metals. The experimental result not only shows the high performance of proposed system but also provides the feasibility of applying differential alignment coil in biologic tissue impedance measurement. Hopefully, these improvements can help the contactless impedance measurement be applied in various fields practically.