Design of a Functional Signal Generator Based on MAX038 and Microcontroller

Hao Hu

doi:10.4028/www.scientific.net/AMR.915-916.1167

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 915-916Design of a Functional Signal Generator Based on...

Design of a Functional Signal Generator Based on MAX038 and Microcontroller

Abstract:

Based on SCM STC89C52 and MAX038, a function signal generator for generating a frequency and amplitude can be programmed to adjust the sine wave, square wave and triangular wave signal. MAX038 function generator with a small amount of peripheral devices are responsible for generating waveforms, which then are input into the LM6361 wideband voltage amplifier and a power amplifier is output. Master STC89C52 is responsible for selecting and managing the waveform types, frequency adjustment, output amplitude adjustment, LCD, and keyboard work of each module operation.

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Periodical:

Advanced Materials Research (Volumes 915-916)

Pages:

1167-1170

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.915-916.1167

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Online since:

April 2014

Authors:

Hao Hu

Keywords:

Functional, MAX038, Microcontroller, Signal Generator

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References

[1] Zhang, M. -J., Liu, T. -G., Wang, A. -B., Zheng, J. -Y., Meng, L. -N., Zhang, Z. -X., & Wang, Y. -C. (2011). Photonic ultrawideband signal generator using an optically injected chaotic semiconductor laser. Optics letters, 36(6), 1008-1010.

DOI: 10.1364/ol.36.001008

Google Scholar

[2] Manikumar, C., Raju, K. N., Ramana, C., Nagamani, G., Sekhar, T. C., & Ebraheem, M. (2011).

Google Scholar

[3] Koran, A., Sano, K., Kim, R. -Y., & Lai, J. -S. (2010). Design of a photovoltaic simulator with a novel reference signal generator and two-stage LC output filter. Power Electronics, IEEE Transactions on, 25(5), 1331-1338.

DOI: 10.1109/tpel.2009.2037501

Google Scholar

[4] Chen, L., Liu, G., Gao, B., Chen, P., & Xiong, X. (2012). Development of a Double-Channel Medical Signal Generator Based on STM32 with High Performance. Open Journal of Applied Sciences, 2, 272.

DOI: 10.4236/ojapps.2012.24040

Google Scholar

[5] Zhong, R. Y., Dai, Q. Y., Zhou, K., & Dai, X. B. (2008). Design and Implementation of DMES Based on RFID. Paper presented at the 2nd International Conference on Anti-counterfeiting, Security and Identification, Guiyang, 20-23 Aug. 475-477.

DOI: 10.1109/iwasid.2008.4688433

Google Scholar

[6] Zhong, R. Y., Dai, Q. Y., Qu, T., Hu, G. J., & Huang, G. Q. (2013). RFID-enabled Real-time Manufacturing Execution System for Mass-customization Production. Robotics and Computer-Integrated Manufacturing, 29(2), 283-292.

DOI: 10.1016/j.rcim.2012.08.001

Google Scholar

[7] Tam, P. D., Hong, H. S., & Hieu, N. V. (2012). Novel portable electrical detection system for DNA SENSOR application. Journal of Experimental Nanoscience(ahead-of-print), 1-9.

DOI: 10.1080/17458080.2012.683536

Google Scholar

[8] Zhong, R. Y., Li, Z., Pang, A. L. Y., Pan, Y., Qu, T., & Huang, G. Q. (2013).

Google Scholar