Very large scale integration (VLSI)-based neuromorphic systems have been evolving quickly in recent years. These systems have been used in complex cognitive tasks such as image classification and pattern recognition. A neuromorphic encoder is an essential component in a neuromorphic system, which converts sensory data into spike trains. The advancement in CMOS technology nodes leads to various reliability issues. Bias temperature instability (BTI) and hot carrier injection (HCI) are major reliability issues in analog/mixed VLSI circuits. This paper implements a temporal neuromorphic encoder, and a corresponding mathematical model is derived for image processing applications. The relationship between an input image pixel value and output of the encoder, that is, interspike interval (ISI), is found to be exponential. The impact of BTI and HCI on the temporal neuromorphic encoder is analyzed. The degradation analysis revealed a loss of encoding functionality for which three mitigation techniques are discussed. Finally, a reliability-aware neuromorphic encoder is proposed to minimize the effect of degradation over its lifetime. The power consumption of conventional and proposed reliability-aware neuromorphic encoders is also presented. © 2021 John Wiley & Sons, Ltd.