Polarizando o MOSFET 20ª Aula: Ao final desta aula você deverá estar apto a: Analisar circuitos de polarização para MOSFETs Projetar circuitos para MOSFETS Explicar a diferença entre as técnicas de análise de circuitos para MOSFETs e para bipolares Explicar o efeito de corpo (porta escondida) sedr42021_0307.jpg PSI2223 1
Exemplo 4.2 Projete o circuito abaixo para ID=400 mA e VD = +0,5V, sabendo-se que Vt=0,7 V, mn Cox = 100 mA/V2, L = 1 mm e W = 32 mm (l = 0). PSI2223 2
Exemplo 4. 3 Projete o circuito abaixo para ID=80 mA. Determine R e VD Exemplo 4.3 Projete o circuito abaixo para ID=80 mA. Determine R e VD. Considere Vt=0,6 V, mn Cox = 200 mA/V2, L = 0,8 mm e W = 4 mm (l = 0). PSI2223 3
Exemplo 4. 4 Projete o circuito abaixo para VD= 0,1V Exemplo 4.4 Projete o circuito abaixo para VD= 0,1V. Qual a resistência efetiva entre dreno e fonte? Considere Vt= 1 V e kn´(W/L) = 1 mA/V2 PSI2223 4
Exemplo 4.5 Analise o circuito abaixo e detrmine todas as tensões nos nós e correntes nos ramos. Considere Vt= 1,0 V e kn´(W/L) =1 mA/V2, PSI2223 5
Exemplo 4.5 Analise o circuito abaixo e detrmine todas as tensões nos nós e correntes nos ramos. Considere Vt= 1,0 V e kn´(W/L) =1 mA/V2, PSI2223 6
Exemplo 4.6 Projete o circuito abaixo para ID=500 mA e VD = +3V, sabendo-se que Vt= −1 V, kp´(W/L) = 1 mA/V2 e (l = 0). PSI2223 7
Exemplo 4.7 O PMOS e o NMOS do circuito abaixo são casados, isto é, kn´(W/L)= kp´(W/L) = 1 mA/V2 e Vtn = - Vtp = 1V. Considerando l = 0 para ambos, determine IDN e IDP e vo para vi = 0V, +2,5V e −2,5V PSI2223 8
Exemplo 4.7 O PMOS e o NMOS do circuito abaixo são casados, isto é, kn´(W/L)= kp´(W/L) = 1 mA/V2 e Vtn = - Vtp = 1V. Considerando l = 0 para ambos, determine IDN e IDP e vo para vi = 0V, +2,5V e −2,5V PSI2223 9
Exemplo 4.7 O PMOS e o NMOS do circuito abaixo são casados, isto é, kn´(W/L)= kp´(W/L) = 1 mA/V2 e Vtn = - Vtp = 1V. Considerando l = 0 para ambos, determine IDN e IDP e vo para vi = 0V, +2,5V e −2,5V PSI2223 10
Exemplo 4.7 O PMOS e o NMOS do circuito abaixo são casados, isto é, kn´(W/L)= kp´(W/L) = 1 mA/V2 e Vtn = - Vtp = 1V. Considerando l = 0 para ambos, determine IDN e IDP e vo para vi = 0V, +2,5V e −2,5V PSI2223 11
Exemplo 4.8!!!!! e 4.12!!! O PMOS e o NMOS do circuito abaixo são casados, isto é, kn´(W/L)= kp´(W/L) = 1 mA/V2 e Vtn = - Vtp = 1V. Considerando l = 0 para ambos, determine IDN e IDP e vo para vi = 0V, +2,5V e −2,5V PSI2223 12
NMOSFET Tipo Depleção (apresenta canal implantado entre fonte e dreno) Porta (G-Gate) Fonte (S-Source) Dreno (D-Drain) M O S N N+ N+ P Substrato (B-Body) Canal implantado Figura 5.20 PSI2223 13
NMOSFET Tipo Depleção (Vt < 0) Figura 5.21 PSI2223 14
NMOSFET Tipo Depleção (Vt < 0) Figura 5.21b PSI2223 15
Características ID-VGS (Tipo Enriquecimento e tipo Depleção) Figura 5.23 PSI2223 16
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O que está por trás do anúncio da Intel IEEE Spectrum: 9 May 2011— Last Wednesday, Intel announced a big change to the electronic switches at the heart of its CPUs. Going forward, the firm will be using three-dimensional transistors to take the place of long-used planar devices. The new transistors—dubbed "tri-gates"—are a variation on the FinFET, a transistor design that substitutes the flat channel through which electrons flow with a 3-D ridge, or fin. Popping the channel out of plane and draping the gate—which switches the transistor on and off—over it will allow Intel to shrink the smallest features in its transistors from 32 nanometers to 22 nm while cutting power consumption in half. This feat would be impossible to do with the transistor design the company had been using. sedr42021_0501.jpg PSI2223 18
O que está por trás do anúncio da Intel sedr42021_0501.jpg PSI2223 19
O que está por trás do anúncio da Intel How did this 3-D design win its way into production? We asked the coinventor of the FinFET, IEEE Fellow Chenming Hu, a professor emeritus at the University of California, Berkeley, how the new transistors got their start, why we need them now, and where they will go from here. sedr42021_0501.jpg PSI2223 20
O que está por trás do anúncio da Intel IEEE Spectrum: We’ve been shrinking two-dimensional, or planar, transistors just fine for 50 years. Why are we seeing a switch to threedimensional FinFETs? Chenming Hu: I’ll distill the problem with planar transistors to a single point. It all stems from the fact that it is very difficult to turn off a transistor when it’s very small. In other words, you can’t stop the current flowing through the transistor when you don’t want the current to flow. I’ll use an analogy to explain this. There is a garden hose lying on a soggy lawn, and you want to stop the water from flowing into this lawn. If there’s a long hose, you can call your friends to come in and put 10 pairs of hands down, andyou can stop the water. Now imagine you shorten the hose so you cannot even put one palm on it to stop it. Now you shorten it even more, so you can only put one finger on it. It’s impossible to stop. In the past 10 years, people have dealt with this garden hose problem in various ways, and one way has been to sacrifice power. For 250-nm transistors, the power-supply voltage was 2.5 volts; for 180 nm, it was 1.8 V; for 130 nm, it was 1.3 V. The pattern was very regular until 90 nm, but it reached a limit. Instead of 0.9 V, you know what the industry used? 1.2 V. Even at 45 nm, the industry still used 0.9 V instead of 0.45 V. sedr42021_0501.jpg PSI2223 21
O que está por trás do anúncio da Intel IEEE Spectrum: So current is leaking even when the transistors are off. To get around that problem, you have to use a higher voltage to make the difference between on and off more obvious? Chenming Hu: Exactly. What’s the consequence of that? Power is proportional to the square of the voltage. So if you use twice as high a voltage as the historical trend, your cellphone will consume four times the power. The pain is just too big to keep going that way. We thought planar technology would run out of steam sometime after 25 nm, and it did. IEEE Spectrum: How do FinFETs help fix the leaky garden hose problem? Chenming Hu: Remember, the hose is on a soggy, soft lawn. So what if instead of pressing your finger on this garden hose, you pinch your fingers on the two sides of the garden hose? That’s the analogy. The weak point, the soggy lawn, is the silicon substrate. So you really have to do something on both sides so you’re pinching against something firm, an that’s what the FinFET is doing. We should pinch the channel [where electrons flow] on two sides and on top. The more pinching sides, the better. Pinching the hose will allow us to use a much, much shorter hose. That’s extremely important. Making things small is really the key of making the electronics cheaper, faster, and lower power. sedr42021_0501.jpg PSI2223 22
O que está por trás do anúncio da Intel IEEE Spectrum: The idea for FinFETs has been around for a while. How did it all get started? Chenming Hu: DARPA [the Defense Advanced Research Projects Agency] sent out a request for proposals in 1996 for ideas to develop electronic switches beyond 25 nm. At the time, the industry was using 250-nm transistors, and the general view was that transistors could not be scaled below 100 nm. But my students and I had already been thinking about how to get transistors to scale to 25 nm and beyond. There was a quick meeting probably lasting only five minutes between myself and two colleagues—Professor Tsu-Jae King Liu and Professor Jeff Bokor. The meeting was short because we already knew what to do. I was on a flight to a conference in Japan, and I had about 10 hours, so I just wrote down the technical proposal in longhand. I proposed two structures that we’d been thinking about for a while. One was FinFETs, and the other is what we call an ultrathin-body silicon-on-insulator (UTB SOI). We got the contract in 1997, and that gave us the resources to demonstrate FinFETs experimentally. A young graduate student named Xuejue "Cathy" Huang made the working device, and the team of three professors and 11 students and visiting researchers published it in 1999. sedr42021_0501.jpg PSI2223 23
O que está por trás do anúncio da Intel sedr42021_0501.jpg PSI2223 24
O que está por trás do anúncio da Intel IEEE Spectrum: How did the industry react to the FinFET paper? Chenming Hu: It was an instant hit. I remember Cathy and I were invited to Intel Santa Clara just a couple of months after the publication, and in that same year, 2000, I was invited to Intel Oregon twice. At the time, people were asking me how long it would take for the idea to get into production. I said about 10 years, so I guess I was off by one. ... sedr42021_0501.jpg PSI2223 25