Result Details
AxMED: Formal Analysis and Automated Design of Approximate Median Filters using BDDs
The increasing demand for energy-efficient solutions has led to the emergence of
an approximate computing paradigm that enables power-efficient implementations in
various application areas such as image and data processing. The median filter,
widely used in image processing and computer vision, is of immense importance in
these domains. We propose a systematic design methodology for the design of
power-efficient median networks suitable for on-chip or FPGA-based
implementations. A search-based design method is used to obtain approximate
medians that show the desired trade-offs between accuracy, power consumption and
area on chip. A new metric tailored to this problem is proposed to quantify the
accuracy of approximate medians. Instead of the simple error rate, our method
analyses the rank error. A significant improvement in implementation cost is
achieved. For example, compared to the well-optimized high-throughput
implementation of the exact 9-input median, a 30% reduction in area and a 36%
reduction in power consumption was achieved by introducing an error by one
position (i.e., allowing the 4th or 6th lowest input to be returned instead of
the median).
approximate computing, median filters, design automation
@inproceedings{BUT194216,
author="Vojtěch {Mrázek} and Zdeněk {Vašíček}",
title="AxMED: Formal Analysis and Automated Design of Approximate Median Filters using BDDs",
booktitle="2025 IEEE International Symposium on Circuits and Systems (ISCAS)",
year="2025",
pages="1--5",
publisher="Institute of Electrical and Electronics Engineers",
address="London",
doi="10.1109/ISCAS56072.2025.11043775",
isbn="979-8-3503-5683-0"
}