1 D. J. R. Cristaldi, "Liquid Crystal Display Drivers-Techniques and Circuits" Springer 2009
2 P. Mok, "Design considerations of recent advanced low-voltage low-temperaturecoefficient CMOS bandgap voltage reference" 635-642, 2004
3 Y. Tokunaga, "An on-chip CMOS relaxation oscillator with voltage averaging feedback" 45 (45): 1150-1158, 2010
4 T. Miki, "An 80-MHz 8-bit CMOS D/A converter" SC-21 : 983-988, 1986
5 A. V. Boas, "A temperature compensated digitally trimmable on-chip IC oscillator with low voltage inhibit capability" 1 : 501-504, 2004
6 F. Sebastiano, "A lowvoltage mobility-based frequency reference for crystal-less ULP radios" 44 (44): 2002-2009, 2009
7 H. Banba, "A CMOS bandgap reference circuit with sub-1-V operation" 34 : 670-674, 1999
8 T. Tokairin, "A 280 nW, 100 kHz, 1-cycle start-up time, on-chip CMOS relaxation oscillator employing a feed-froward period control scheme" 16-17, 2012
9 J. Lee, "A 10 MHz 80 μW 67 ppm/°C CMOS reference clock oscillator with a temperature compensated feedback loop in 0.18 μm CMOS" 226-227, 2009
1 D. J. R. Cristaldi, "Liquid Crystal Display Drivers-Techniques and Circuits" Springer 2009
2 P. Mok, "Design considerations of recent advanced low-voltage low-temperaturecoefficient CMOS bandgap voltage reference" 635-642, 2004
3 Y. Tokunaga, "An on-chip CMOS relaxation oscillator with voltage averaging feedback" 45 (45): 1150-1158, 2010
4 T. Miki, "An 80-MHz 8-bit CMOS D/A converter" SC-21 : 983-988, 1986
5 A. V. Boas, "A temperature compensated digitally trimmable on-chip IC oscillator with low voltage inhibit capability" 1 : 501-504, 2004
6 F. Sebastiano, "A lowvoltage mobility-based frequency reference for crystal-less ULP radios" 44 (44): 2002-2009, 2009
7 H. Banba, "A CMOS bandgap reference circuit with sub-1-V operation" 34 : 670-674, 1999
8 T. Tokairin, "A 280 nW, 100 kHz, 1-cycle start-up time, on-chip CMOS relaxation oscillator employing a feed-froward period control scheme" 16-17, 2012
9 J. Lee, "A 10 MHz 80 μW 67 ppm/°C CMOS reference clock oscillator with a temperature compensated feedback loop in 0.18 μm CMOS" 226-227, 2009