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| bipolar:start [2012/05/27 07:43] – [Buried layers] mcmaster | bipolar:start [2016/01/03 06:29] (current) – mcmaster | ||
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| + | FIXME: cleanup | ||
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| This page is very research orientated and information on it should not be trusted. | This page is very research orientated and information on it should not be trusted. | ||
| TODO: this page should eventually have only compound logic gates, but is currently a sandbox for basic components. I'd like to substitute out these pictures for ones free of copyright issues to avoid any potential issues. | TODO: this page should eventually have only compound logic gates, but is currently a sandbox for basic components. I'd like to substitute out these pictures for ones free of copyright issues to avoid any potential issues. | ||
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| ====== Resistor ====== | ====== Resistor ====== | ||
| Resistors seem to be grouped on islands with many other resistors. Resistance is a factor of the length of the trace, dopant, etc. | Resistors seem to be grouped on islands with many other resistors. Resistance is a factor of the length of the trace, dopant, etc. | ||
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| {{gallery> | {{gallery> | ||
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| + | {{: | ||
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| In MOS circuitry, resistors are avoided as much as possible as it is often much more cost effective to utilize transistors to form an equivalent circuit. | In MOS circuitry, resistors are avoided as much as possible as it is often much more cost effective to utilize transistors to form an equivalent circuit. | ||
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| Here is the raw transistor: | Here is the raw transistor: | ||
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| {{: | {{: | ||
| Its a little hard to see so heres a red outline around it: | Its a little hard to see so heres a red outline around it: | ||
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| {{: | {{: | ||
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| + | ====== Bipolar transistor ====== | ||
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| + | [[bipolar: | ||
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| + | {{gallery>: | ||
| + | |{{gallery>: | ||
| + | |Contacts from left to right: collector, emitter, base. The collector forms the bulk of the well. Assuming its an NPN (which it may or may not be), you can also see the p-isolation in blueish-green around the edges. The base forms the larger white area around the emitter. Traces of the metal contacts can be seen as darker regions on the collector' | ||
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| + | {{gallery>: | ||
| + | Discrete bipolar transistor from TO-3 package. | ||
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| + | Another bipolar description: | ||
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| + | ====== Mesa transistor ====== | ||
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| + | {{gallery>: | ||
| + | {{gallery>: | ||
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| + | Diffusion transistor. Does not use photolithography. Above image shows the mesa shape versus other transistor which were more or less flat. | ||
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| + | Name comes from the physical mesa shape. Indications that this is because of the component geometries, but also read something that indicated its because they used acid (probably HF) to etch it out and it gets the shape because it etches more on the top by the time it gets to the bottom. Modern dicing is either through scribing or sawing. | ||
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| + | ====== Planar transistor ====== | ||
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| + | Uses photolithography to print transistors. Has SiO2 passivation. Significantly reduced cost and significant increase in quality. | ||
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| + | ====== Diffusion transistor ====== | ||
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| + | Wafer is put into a high temperature oven and doped by gas diffusing into the silicon. | ||
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| + | ====== Lateral transistor ====== | ||
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| + | "It is the world' | ||
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| ====== References ====== | ====== References ====== | ||
| + | - http:// | ||
| - Encylopedia Britanica: http:// | - Encylopedia Britanica: http:// | ||
| - UC Berkeley EE 105 Microelectronics: | - UC Berkeley EE 105 Microelectronics: | ||
| + | - http:// | ||
| + | - http:// | ||