طراحی و شبیهسازی یک ضربکننده خازنی جدید با بایاس جریان تطبیقی و تکنیک گیت شبهشناور با ویژگی تنظیمپذیری الکترونیکی و خطینگی بالا برای کاربردهای زیستپزشکی
محورهای موضوعی : مدارهای مجتمع الکترونیک
محمد آقایی جشوقانی
1
,
مهدی دولتشاهی
2
,
سید محمد علی زنجانی
3
,
محمدامین هنرور
4
1 - دانشکده مهندسی برق- واحد نجفآباد، دانشگاه آزاد اسلامی، نجفآباد، ایران
2 - دانشکده مهندسی برق- واحد نجفآباد، دانشگاه آزاد اسلامی، نجفآباد، ایران
3 - مرکز تحقیقات ریز شبکه های هوشمند- واحد نجف آباد، دانشگاه آزاد اسلامی، نجف آباد، ایران
4 - مرکز تحقیقات ریز شبکه های هوشمند- واحد نجف آباد، دانشگاه آزاد اسلامی، نجف آباد، ایران
کلید واژه: جریان تطبیقی, تنظیمپذیری الکترونیکی, خطینگی, زیست پزشکی, ضربکننده خازنی,
چکیده مقاله :
استفاده از ضربکنندههای خازنی در مدارهای مجتمع فرکانس پایین، تاثیر قابل توجه در کاهش مساحت تراشه دارد. در مدار پیشنهادی بهمنظور کاهش مقاومت معادل سری در طبقه ورودی از ساختار مبتنیبر دنبالکننده جریان بازگشتی استفاده شده است. استفاده از مدار کمکی جهت تطبیق جریان بایاس ترانزیستورها و اعمال سیگنالهای لازم توسط تکنیک گیت شبهشناور بهمنظور کاهش توان مصرفی ایستا و افزایش خطینگی از دیگر ویژگیهای مدار پیشنهادی است. همچنین جهت افزایش خطینگی از فیدبک منفی استفاده شده است تا ولتاژ لازم به گیت ترانزیستورهای نمونهبردار جریان اعمال شود. ضریب مقیاسگذاری K با روش فعال قابل تنظیم است. مقاومت ورودی پایین و مقاومت خروجی بالا و حداقل مساحت مدار پیشنهادی، از نتایج نظری و شبیهسازی مدار پیشنهادی است. مدار پیشنهادی در فناوری 18/0 میکرومتر و با تغذیه 8/0 ولت شبیهسازی شده است. نتایج نشان میدهد مدار پیشنهادی برای خازن معادل 204 پیکوفاراد با خازن پایه 1 پیکو فاراد، توانی معادل 850 نانووات مصرف میکند. بهعنوان مثالی دیگر، برای تحقق خازن 101 پیکو فاراد با تغذیه و خازن پایه مذکور، ضربکننده پیشنهادی، به مساحتی 3/6 بار کمتر و پهنای باند 23 بار بیشتر نسبت به FCF نیاز دارد که نشانگر افزایش صحت طرح پیشنهادی است. در مدار پیشنهادی، با حضور مدار تطبیق جریان با دامنه سیگنال 7 نانوآمپر در ورودی، دامنه سیگنال جریان خروجی 1510 نانو آمپر است؛ در حالی که جریان بایاس خروجی 100 نانوآمپر بوده و مقدار اعوجاج هارمونیکی 6/3 درصد است. مدار پیشنهادی دارای بیشترین ضریب شایستگی یعنی 823/48 مگاهرتز بر میکرووات است که معرف عملکرد بهتر نسبت به مدارهای گزارششده قبلی است.
Employing capacitance multipliers in low-frequency integrated circuits has a significant effect on reducing the chip size area. The main idea behind the proposed circuit in this paper is to use a folded current follower (FCF) structure to effectively reduce the equivalent series resistance (ESR) in the input stage. Furthermore, using an auxiliary circuit to adapt the bias current of the transistors and applying the necessary signals by the quasi-floating gate technique (QFG), are other approaches employed to reduce the static power consumption while properly increasing the linearity of the proposed circuit, which can be considered as other benefits of the proposed approach. On the other hand, to improve the linearity, negative feedback is used and necessary voltage is applied to the gate of the transistors in the current sampler. The “K” coefficient can be adjusted by the active method. Low input resistance and high output resistance as well as the reduced occupied silicon area are achieved based on the simulation results of the proposed circuit. The simulation results in 0.18 μm technology show that, with a 0.8 V power supply and base capacitor (Cb=1 pF), for 850 nW power consumption, a capacitor equivalent to 204 pF is achieved in the proposed approach. As another example, to realize the 101 pF capacitor with the supply as mentioned above and base capacitor, the proposed multiplier requires 6.3 times less area and 23 times more bandwidth than FCF, which shows the increased accuracy of the proposed design. In the proposed circuit, in the presence of a current adaptive circuit with an input signal range of 7 nA, the output current range is obtained as 1510 nA, While the output bias current is 100nA and the harmonic distortion value is obtained as 3.6%. The proposed circuit has the highest figure of merit 42.823 MHz/μW, which shows superiority in overall performance in comparison with other reported designs.
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