A simple two-step process was used to disperse acid functionalizedmulti-walled carbon nanotubes (CNTs) in poly(vinylidene fluoride) (PVDF).While the neat solvent-cast PVDF showed coexistence of α- and β-phases; the composite films exhibited only β-phase crystals. Further studies on the crystalline behaviour, using differential scanning calorimetry and small-angle X-ray scattering techniques showed an increase in the percentage of crystalline phase with CNT. The network formed by CNTs in the matrix reduced the macroscopic electrical resistivity of composite films. The dielectric constant increased with CNT loading. Further, these composites were investigated for its electromagnetic wave absorbance (EWA) and strain sensing properties. The EWA properties were studied in the X-band (6–12 GHz) region. A maximum of ~37 dB reflectivity loss at ~9.0 GHz was obtained in a ~25 lm thick PVDF film containing only 0.25 wt%of functionalizedCNT. Preliminary studies showed a systematic change in electrical resistance by the application of dynamic bending strain in nanocomposite film. The film also showed a significant improvement in mechanical stiffness owing to efficient stress transfer frommatrix to filler, the property desirable for a good strain sensor. In view of the unique combination of EWA and electro-mechanical properties,  the nanocomposite films are expected to serve as a multifunctional material for strain sensing in health monitoring as well as in radar absorption.