@article{ghosh_zhou_2003, title={Characterization of fabric bending behavior: A review of measurement principles}, volume={28}, number={4}, journal={Indian Journal of Fibre & Textile Research}, author={Ghosh, T. K. and Zhou, N. Y.}, year={2003}, pages={471–476} }
 @article{zhou_ghosh_1999, title={On-line measurement of fabric bending behavior Part III: Dynamic considerations and experimental implementation}, volume={69}, DOI={10.1177/004051759906900304}, abstractNote={ A nonlinear, dynamic fabric bending model is introduced to study the dynamic effects on loop formation and measured characteristic parameters. In order to verify the theoretical results and test the measurement principle, an experimental system based on the principles of loops 3 and 4 is developed. The influence of fabric linear speed and movement direction on the measured values is discussed. Discrepancies between theoretical and experimental observations indicate that a full understanding of the ef fects of the fabric bending rate on bending properties is necessary to accurately model bending behavior when a high bending rate is involved. The work demonstrates a strong correlation between the on-line and off-line measured results. }, number={3}, journal={Textile Research Journal}, author={Zhou, N. Y. and ghosh}, year={1999}, pages={176–184} }
 @article{zhou_ghosh_1998, title={On-line measurement of fabric bending behavior Part II: Effects of fabric nonlinear bending behavior}, volume={68}, DOI={10.1177/004051759806800711}, abstractNote={ A generalized fabric bending model is developed based on the nonlinear bending moment-curvature relationship of fabrics. This model makes it possible to theoretically investigate the effects of fabric nonlinear bending behavior on measured bending prop erty values. The dependence of measured parameters (e.g., bending length, bending rigidity) on the conditions for the cantilever and heart loop, loop 3, and loop 4 tests is determined theoretically. Calculated results show good agreement with experimental observations reported in the literature for the cantilever and heart loop. An important discovery in this investigation is that the bending length values calculated and measured from loop 3 and loop 4 are not influenced by fabric sample length if that length is beyond a certain critical value. }, number={7}, journal={Textile Research Journal}, author={Zhou, N. Y. and ghosh}, year={1998}, pages={533–542} }
 @article{zhou_ghosh_1998, title={On-line measurement of fabric bending behavior: background, need and potential solutions}, volume={10}, DOI={10.1108/09556229810213845}, abstractNote={Low‐stress mechanical properties of fabrics are very important in many applications as well as in manufacturing process control. Discusses the importance and potential applications of an on‐line mechanical property measurement system. In addition, the working principles of existing off‐ line fabric bending testers have been critically reviewed. It is suggested that the principle of a future on‐line system to evaluate fabric bending behaviour should be based on the characterisation of fabric loop shapes. }, number={2}, journal={International Journal of Clothing Science and Technology}, author={Zhou, N. Y. and ghosh}, year={1998}, pages={143–154} }
 @article{zhou_ghosh_1997, title={On-line measurement of fabric bending behavior .1. Theoretical study of static fabric loops}, volume={67}, ISSN={["1746-7748"]}, DOI={10.1177/004051759706701003}, abstractNote={ In order to develop an on-line system to characterize fabric bending rigidity, four potential loop shapes are proposed. Loop shapes are chosen such that they can be formed under dynamic conditions. Results from theoretical models of these loops show the nature of the response of loop shapes to varying fabric bending behaviors. Two candidate loop shapes are identified for further investigation under nonlinear and dynamic conditions. }, number={10}, journal={TEXTILE RESEARCH JOURNAL}, author={Zhou, NYM and Ghosh, TK}, year={1997}, month={Oct}, pages={712–719} }