Recent enhancements in military telecommunication systems for monitoring and tracking in low VHF range (30-80 MHz) implies the use of specific antenna measurement facilities to characterize either the antenna alone or the antenna mounted on a supporting structure which can be heavy and bulky. Conventional outdoor far-field antenna measurement ranges used at UHF frequency bands and above become poorly effective down in VHF frequency band due to ground effects and electromagnetic pollution. Other implementations such as indoor far-field or compact range are not suitable at these very large wavelengths. The multi-sensor near-field approach shows benefits in terms of compactness and measurement speed. However this approach involves considering and treating high levels of reflectivity of anechoic chambers, positioners and structures at these frequencies. The implementation of such an antenna measurement range thus requires identifying and characterizing the effects of each contributor on the measurement performance and accuracy. In a first step, the proposed paper focuses on the feasibility of an indoor measurement facility at VHF frequencies with reflectivity analyses of each constituting elements of the multi-sensor near-field range (anechoic chamber, mast, positioner and measurement probes). Performances of the ferrite tiles as a low frequency absorbing solution covering anechoic chamber walls are estimated through 3D EM simulation and analytical model. A global measurement error budget is established for different antenna directivity classes. In a second step, activities are dedicated to an outdoor near field range including analysis of reflectivity (floor, probes, arch, tent …) and estimation of system performance. Mechanical aspects to obtain a removable and transportable system are discussed and considered in the global budget error. Finally both indoor and outdoor multi-sensor solutions are compared in terms of performances to conclude on the feasibility of such facilities and to identify key points.