| # | Document title | Authors | Year | Source | Cited by |
| 1 | An energy-efficient micropower neural recording amplifier | Wattanapanitch W., Fee M., Sarpeshkar R. | 2007 | IEEE Transactions on Biomedical Circuits and Systems
1(2),pp. 136-147 | 348 |
| 2 | A low-power 32-channel digitally programmable neural recording integrated circuit | Wattanapanitch W., Wattanapanitch W., Sarpeshkar R. | 2011 | IEEE Transactions on Biomedical Circuits and Systems
5(6),pp. 592-602 | 108 |
| 3 | Low-power circuits for brain-machine interfaces | Sarpeshkar R., Wattanapanitch W., Arfin S., Rapoport B., Mandal S., Baker M., Fee M., Musallam S., Andersen R. | 2008 | IEEE Transactions on Biomedical Circuits and Systems
2(3),pp. 173-183 | 61 |
| 4 | Low-power circuits for brain-machine interfaces | Sarpeshkar R., Wattanapanitch W., Rapoport B.I., Arfin S.K., Baker M.W., Mandal S., Fee M.S., Musallam S., Andersen R.A. | 2007 | Proceedings - IEEE International Symposium on Circuits and Systems
,pp. 2068-2071 | 22 |
| 5 | Efficient Universal Computing Architectures for Decoding Neural Activity | Rapoport B., Rapoport B., Turicchia L., Wattanapanitch W., Davidson T., Sarpeshkar R. | 2012 | PLoS ONE
7(9) | 16 |
| 6 | A biomimetic adaptive algorithm and low-power architecture for implantable neural decoders | Rapoport B., Rapoport B., Wattanapanitch W., Penagos H., Musallam S., Andersen R., Sarpeshkar R. | 2009 | Proceedings of the 31st Annual International Conference of the IEEE Engineering in Medicine and Biology Society: Engineering the Future of Biomedicine, EMBC 2009
,pp. 4214-4217 | 11 |
| 7 | Graphical analysis and design of multistage operational amplifiers with active feedback Miller compensation | Tepwimonpetkun S., Pholpoke B., Wattanapanitch W. | 2016 | International Journal of Circuit Theory and Applications
44(3),pp. 562-583 | 5 |
| 8 | Design of a low-power high open-loop gain operational amplifier for capacitively-coupled instrumentation amplifiers | Prasopsin P., Wattanapanitch W. | 2017 | International Journal of Circuit Theory and Applications
45(11),pp. 1552-1575 | 3 |
| 9 | A Micropower Motion Artifact Estimator for Input Dynamic Range Reduction in Wearable ECG Acquisition Systems | Pholpoke B., Songthawornpong T., Wattanapanitch W. | 2019 | IEEE Transactions on Biomedical Circuits and Systems
13(5),pp. 1021-1035 | 2 |
| 10 | A 2.64-\mu \mathrm{W} 71-dB SNDR Discrete-Time Signal-Folding Amplifier for Reducing ADC's Resolution Requirement in Wearable ECG Acquisition Systems | Ratametha C., Tepwimonpetkun S., Wattanapanitch W. | 2020 | IEEE Transactions on Biomedical Circuits and Systems
14(1),pp. 48-64 | 2 |
| 11 | A compact low-power mixed-signal architecture for powerline interference rejection in biopotential analog front ends | Prasopsin P., Pholpoke B., Tepwimonpetkun S., Wattanapanitch W. | 2014 | IEEE 2014 Biomedical Circuits and Systems Conference, BioCAS 2014 - Proceedings
,pp. 196-199 | 2 |
| 12 | A Low-Power High-Input-Impedance 70-dB Gain ECG Readout System with High Interference Tolerance | Ratametha C., Buaban C., Pholpoke B., Limpisawas T., Prasopsin P., Tepwimonpetkun S., Wattanapanitch W. | 2018 | 2018 IEEE Biomedical Circuits and Systems Conference, BioCAS 2018 - Proceedings
| 1 |
| 13 | A 10 Gb/s optical receiver in 0.25 μm silicon-on-sapphire CMOS | Chen P.C.P., Pappu A.M., Fu Z., Wattanapanitch W., Apsel A.B. | 2008 | Proceedings - IEEE International Symposium on Circuits and Systems
,pp. 193-196 | 0 |
| 14 | A Low-Power High-Input-Impedance ECG Readout System Employing A Very High-Gain Amplification and A Signal-Folding Technique for Dry-Electrode Recording | Buaban C., Ratametha C., Limpisawas T., Songthawornpong T., Pholpoke B., Wattanapanitch W. | 2021 | IEEE Sensors Journal
| 0 |