A 100 mA Low Voltage Linear Regulators for Systems on Chip Applications Using 0.18 um CMOS Technology
A novel design for a low dropout (LDO) voltage regulator is presented and dedicated to power many sections of a typical cellular handset. However, these baseband, RF, and audio sections have different requirements that influence which LDO is most appropriate. After discussion of the specific requirements, different LDOs are recommended. Also, some LDO design techniques are briefly discussed to demonstrate how an LDO may be optimized for a specific level of performance.
Cellular phone designs require linear regulators with low-dropout, low-noise, high PSRR, low quiescent current (Iq), and low-cost. They need to deliver a stable output and use small-value output capacitors. Ideally, one device would have all these characteristics and one low-dropout linear regulator (LDO) could be used anywhere in the phone without worry. But in practice, the various cell phone blocks are best powered by LDOs with different performance characteristics. This paper provides a new design methodology to choosing the right LDO to power each cell phone and especially for the Voltage Phase-Locked loops (VPLLs) blocks. Fabricated in a 0.18 m CMOS process, the measured results show the adopted topology achieves a better phase noise than the conventional saturation current source. and the spread of the current limitation (without matching) is 100mA, the VPLLs system demonstrates a phase noise of 782 nv/sqrtHz at 100-kHz, and 33 nv/sqrtHz at 1 MHz, while quiescent current 33 A from a 2.6 V supply voltage.
Keywords: LDO, PSRR, low noise, cell phone, handset, RF, baseband, audio, GSM
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ABOUT THE AUTHORS
Krit Salah-Ddine
Salah-ddine Krit received the B.S. and Ph.D degrees in Microectronics Engineering from Fes Sidi Mohammed Ben Abdellah university, Fez, Morroco. Institute in 2004 and 2009, respectively. During 2002-2008, he is also an engineer Team lead in audio and power management Integrated Circuits (ICs) Research. Design, simulation and layout of analog and digital blocks dedicated for wireless sensor networks (WSN) and satellite communication systems using CMOS technology. He is currently a professor with Polydisciplinary Faculty of Ouarzazate, Ibn Zohr university, Agadir, Morroco. His research interests include wireless sensor Networks (Software and Hardware), microtechnology and nanotechnology for wireless communications.
Zared Kamal
University Sidi Mohamed Ben Abdellah, Technical and Sciences Faculty, Laboratory of Signals, Systems and Components, Morocco.
Qjidaa Hassan
University Sidi Mohamed Ben Abdellah, Technical and Sciences Faculty, Laboratory of Signals, Systems and Components, Morocco.
Zouak Mohcine
University Sidi Mohamed Ben Abdellah, Technical and Sciences Faculty, laboratory of Signals, Systems and Components, Morocco
Krit Salah-Ddine
Salah-ddine Krit received the B.S. and Ph.D degrees in Microectronics Engineering from Fes Sidi Mohammed Ben Abdellah university, Fez, Morroco. Institute in 2004 and 2009, respectively. During 2002-2008, he is also an engineer Team lead in audio and power management Integrated Circuits (ICs) Research. Design, simulation and layout of analog and digital blocks dedicated for wireless sensor networks (WSN) and satellite communication systems using CMOS technology. He is currently a professor with Polydisciplinary Faculty of Ouarzazate, Ibn Zohr university, Agadir, Morroco. His research interests include wireless sensor Networks (Software and Hardware), microtechnology and nanotechnology for wireless communications.
Zared Kamal
University Sidi Mohamed Ben Abdellah, Technical and Sciences Faculty, Laboratory of Signals, Systems and Components, Morocco.
Qjidaa Hassan
University Sidi Mohamed Ben Abdellah, Technical and Sciences Faculty, Laboratory of Signals, Systems and Components, Morocco.
Zouak Mohcine
University Sidi Mohamed Ben Abdellah, Technical and Sciences Faculty, laboratory of Signals, Systems and Components, Morocco
