<div class="section abstract"><div class="htmlview paragraph">The maximum equivalent plastic strain (EPS_max), which can be achieved in the gauge region of a cruciform specimen during in-plane biaxial tensile tests, is limited due to early fracture on the cruciform specimen arm. In this paper, a theoretical model was proposed to determine the factors related to the EPS_max of a cruciform specimen following ISO 16842: 2014. Biaxial tensile tests were carried out to verify the theoretical analyses. Results show that the material strength coefficient (<i>k</i>) has no effect on the EPS_max, and EPS_max increases with the increase of the material hardening exponent (<i>n</i>) and the cross-sectional-area ratio (<i>c</i>) of the arm region to the gauge region. It is found that the applied load ratio (<i>α</i>) has an effect on EPS_max, which decreases as the load ratio increases from 0:1 (i.e. uniaxial tension) to 1:2 (i.e. plane strain state) and then increases as the load ratio increases to 1:1 (i.e. balanced biaxial tension).</div></div>