Abstract
This chapter gives a detailed description of analogue and mixed-signal circuit design, focusing in particular on the S2S printed organic complementary technology. The design and characterisation of several building blocks based on different architectures are shown. After discussing simple differential OTAs, a mismatch-free comparator exploiting offset-cancellation techniques is demonstrated. This circuit is able to resolve differential input voltages as small as 50 mV for a Vdd of 40 V: a remarkable sensitivity for printed electronics. A printed DAC, the first ever demonstrated, is also shown. This DAC, based on a “R-2R” resistive network, achieves a maximum INL of 0.04 LSB at a resolution level of 4 bits. In addition, the HF behaviour of printed diode-connected OTFTs is studied and a four-stage rectifier is presented.
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- 1.
In a “reader-talks-first” RFID system, the reader sends an energising field (a carrier signal typically at radio frequency) which is modulated with a call message to the transponders. The tags need to demodulate and read this call message (typically AM modulated due to simplicity), before deciding whether to answer the reader. In a “tag-talks-first” system, on the other hand, the reader just sends the energising field with no modulation, and tags send a response as soon as they convert the energising field to power.
- 2.
From the definition of mobility, assuming a constant electric field in the channel, we have \( {t}_{flight}={L}^2/\mu {V}_{DS} \).
References
M.G. Kane et al., Analog and digital circuits using organic thin-film transistors on polyester substrates. IEEE Electron Device Lett. 21(11), 534–536 (2000)
N. Gay, W.-J. Fischer, Analog signal processing with organic FETs, in IEEE International Solid State Circuits Conference. Digest of Technical Papers (IEEE, Washington, DC, 2006), pp. 1070–1071
I. Nausieda et al., Mixed-signal organic integrated circuits in a fully photolithographic dual threshold voltage technology. IEEE Trans. Electron Devices 58(3), 865–873 (2011)
H. Marien et al., Analog techniques for reliable organic circuit design on foil applied to an 18 dB single-stage differential amplifier. Org. Electron. 11, 1357–1362 (2010)
D. Raiteri et al., A tunable transconductor for analog amplification and filtering based on double-gate organic TFTs, in Proceedings of the European Solid-State Circuits Conference (IEEE, Washington, DC, 2011), pp. 415–418
H. Marien et al., DC-DC converter assisted two-stage amplifier in organic thin-film transistor technology on foil, in Proceedings of the European Solid-State Circuits Conference (IEEE, Washington, DC, 2011), pp. 411–414
H. Marien et al., A fully-integrated delta-sigma ADC in organic thin-film transistor technology on flexible plastic foil. IEEE J. Solid State Circ. 46(1), 276–284 (2011)
D. Raiteri et al., An organic VCO-based ADC for quasi-static signals achieving 1LSB INL at 6b resolution, in IEEE International Solid State Circuits Conference. Digest of Technical Papers (IEEE, Washington, DC, 2013), pp. 108–109
W. Xiong et al., A 3V 6b successive-approximation ADC using complementary organic thin-film transistors on glass, in IEEE International Solid State Circuits Conference. Digest of Technical Papers (IEEE, Washington, DC, 2010), pp. 134–135
V. Vaidya et al., An organic complementary differential amplifier for flexible AMOLED applications, in Proceedings of IEEE International Symposium on Circuits and Systems (IEEE, Washington, DC, 2010), pp. 3260–3263
M. Guerin et al., High-gain fully printed organic complementary circuits on flexible plastic foils. IEEE Trans. Electron Devices 58(10), 3587–3593 (2011)
A. Knobloch et al., Fully printed integrated circuits from solution processable polymers. J. Appl. Phys. 96, 2286–2291 (2004)
M. Bohm et al., Printable electronics for polymer RFID applications, in IEEE International Solid State Circuits Conference. Digest of Technical Papers (IEEE, Washington, DC, 2006), pp. 1034–1035
R. Blache et al., Organic CMOS circuits for RFID applications, in IEEE International Solid State Circuits Conference. Digest of Technical Papers (IEEE, Washington, DC, 2009), pp. 208–209
T. Someya et al., Printed organic transistors: toward ambient electronics, in International Electron Devices Meeting (IEEE, Washington, DC, 2009), pp. 1–6
W. Smaal et al., Complementary integrated circuits on plastic foil using inkjet printed n- and p-type organic semiconductors: fabrication, characterization, and circuit analysis. Org. Electron. 13, 1686–1692 (2012)
A. Daami et al., Fully printed organic CMOS technology on plastic substrates for digital and analog applications, in IEEE International Solid State Circuits Conference. Digest of Technical Papers (IEEE, Washington, DC, 2011), pp. 328–329
S. Abdinia et al., Variation-based design of an AM demodulator in a printed complementary organic technology. Org. Electron. 15, 904–912 (2014)
S. Abdinia et al., Design of analog and digital building blocks in a fully-printed complementary organic technology, in Proceedings of the European Solid-State Circuits Conference (IEEE, Washington, DC, 2012), pp. 145–148
G. Maiellaro et al., High-gain operational transconductance amplifiers in a fully printed complementary organic TFT technology on flexible foil. IEEE Trans. Circ. Syst. I 60(12), 3117–3125 (2013)
K. Azadet et al., A mismatch-free CMOS dynamic voltage comparator, in Proceedings of IEEE International Symposium on Circuits and Systems (IEEE, Washington, DC, 1995), pp. 2116–2119
S. Abdinia et al., A 4-bit ADC manufactured in a fully-printed organic complementary technology including resistors, in IEEE International Solid State Circuits Conference. Digest of Technical Papers (IEEE, Washington, DC, 2013), pp. 106–107
S. Abdinia et al., A printed DAC achieving 0.4LSB maximum INL at 7b resolution level. Paper Presented at Proceedings of ICT.OPEN 2013, Eindhoven, The Netherlands, 27–28 November, 2013
P. Baude et al., Pentacene-based radio-frequency identification circuitry. Appl. Phys. Lett. 82(22), 3964–3966 (2003)
S. Steudel et al., 50MHz rectifier based on an organic diode. Nat. Mater. 4, 597–600 (2005)
K. Myny et al., An integrated double half-wave organic Schottky diode rectifier on foil operating at 13.56 MHz. Appl. Phys. Lett. 93(9), 093305.1–093305.3 (2008)
K. Lilja et al., Gravure printed organic rectifying diodes operating at high frequencies. Org. Electron. 10, 1011–1014 (2009)
J.F. Dickson, On-chip high-voltage generation in NMOS integrated circuits using an improved voltage multiplier technique. IEEE J. Solid State Circ. 11(3), 374–378 (1976)
G. Papotto et al., A 90-nm CMOS threshold-compensated RF energy harvester. IEEE J. Solid State Circ. 46(9), 1985–1997 (2011)
J.F. Dickson, Voltage multiplier employing clock gated transistor chain, U.S. patent 4214174A, 1980
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Abdinia, S., van Roermund, A.H.M., Cantatore, E. (2015). Analogue and Mixed-Signal Circuit Design. In: Design of Organic Complementary Circuits and Systems on Foil. Analog Circuits and Signal Processing. Springer, Cham. https://doi.org/10.1007/978-3-319-21188-6_5
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DOI: https://doi.org/10.1007/978-3-319-21188-6_5
Publisher Name: Springer, Cham
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