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Resources

https://www.boulderes.com/resource-library/switched-on-mosfet-selection-guide

https://www.digikey.ca/en/blog/how-to-select-a-mosfet-for-logic-circuits-or-gate-design

https://www.youtube.com/watch?v=-dcINC62xyY

What is MOSFET: Symbol, Working, Types & Different Packages (components101.com)

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  • 4 terminals (Source, Drain, Gate, Body)

  • HIgher potential terminal is the drain and other is source. Electrons are carried from the source to the drain (current flows in opposite direction)

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  • 2 Types

    • Enhancement: There Normally Open, there is no initial channel between drain and source (No current at VG = 0). The transistor requires the Gate-Source voltage (VGS) to switch the device “OFF”. The depletion-mode MOSFET is equivalent to a “Normally Closed” switch. (MOST USED)

      • For the n-channel, there is an n-channel between source and drain when the voltage exceeds the threshold, allowing current flow from drain to source.

    • Depletion: There is an initial channel between drain and source (Current at VG = 0). The transistor requires a Gate-Source voltage(VGS) to switch the device “ON”. The enhancement-mode MOSFET is equivalent to a “Normally Open” switch.

      • For the n-channel, a negative voltage is required to deplete the channel. Below the threshold voltage, there is no channel to allow current flow from drain to source.

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  1. Operating Junction and Storage Temperature Range.

    1. Most important item in the absolute maximum ratings list.

    2. Most MOSFETs are rated either at a maximum +150°C or +175°C junction temperature.

  2. Junction-to-Case thermal resistance RθJC.

    1. Example: Thermal resistance of 0.50 °C/W means that for each watt of power dissipated in the junction, the junction temperature will rise 0.5 °C above the case temperature.

  3. Drain-to-Source Breakdown Voltage.

    1. MOSFET can be controlled below the breakdown voltage.

    2. As long as the voltage across drain-to-source is below the threshold, the drain current will not exceed its threshold (there is uncertainty if this voltage limit is exceeded).

    3. Most MOSFETs aren’t used up to its full rated voltage; instead, derating in the 60-70% range is common (inductive spikes may exceed the breakdown voltage)

  4. Static Drain-to-Source On-Resistance RDS(on)

    1. Used to ensure that the voltage drop across the switch is acceptable given a specific current level.

    2. If you are using a MOSFET as a switch and cannot meet the on-resistance spec, don’t use it. 

    3. Example: If you supply a logic output from 3.3V system to the MOSFET via the gate, you cannot MOSFETs spec’d at 4.5V, since there’s not enough voltage to guarantee a full turn-on. Simply using“5V” logic (a logic 1 (HIGH) from a 3.3 V device will be at least 2.4 V Logic Levels - learn.sparkfun.com) doesn’t mean the actual output high voltage will be 5V.

    4. That’s why logic-level MOSFETs are generally specified at 4.5V Vgs, to ensure your output high level is above this threshold.

    5. Failing to meet the Vgs spec may lead to the drain-to-source resistance being generally higher than the RDS(on) spec.

  5. Gate Threshold Voltage VGS(th).

    1. Voltage at which the MOSFET just barely starts to conduct.

    2. Example: The IRFP260N lists 2.0-4.0V for a drain current of 250uA. Concluding that a VGS of 4.5V is sufficient to turn the device on is WRONG. You need the full 10V. 

    3. However, it is useful formaking sure the device is off, where zero voltage between gate and source is ideal to hold the MOSFET off. (This is IDEAL, but no no gate driver is perfect in that regard)

    4. If the driven gate voltage is below the minimum gate threshold of 2.0V, might be acceptable to turn a MOSFET off, and less than threshold current will flow.

    5. Good for power applications, but for signal applications, a quantity such as 250uA is a large number, and most MOSFETs won’t stay completely off (RESEARCH THIS MORE)

  6. Gate Charge.

    1. Determines how fast the MOSFET will switch from ON to OFF and back.

    2. Just divide total gate charge by the gate driver current to determine this time.

    3. Example: With a I have a 1A gate driver, 234nC will take up to 234ns to turn completely on or off.

  7. Turn-on, Rise, Turn-off, and Fall times.

    1. Useful only for understanding the minimum switching times.

    2. Usually gate drive circuit won’t switch as fast as these numbers, and are helpful only as a rough frame of reference.

  8. Input Capacitance (Ciss): The combination of the gate, oxide layer, and body connection of a MOSFET act as a small capacitor that begins charging when voltage is present at the gate. It takes time to charge which results in an ON-state delay. Choose a MOSFET with the lowest input capacitance possible to avoid long delays and minimize in-rush current which can be very high initially but lessens as the capacitor charges.

  9. Channel Type (N channel or P channel):

    1. Channel Type refers to the construction of the silicon inside the device. N channel MOSFETs will turn on with a positive voltage on the gate relative to the source while P channel MOSFETs will turn on with a negative voltage on the gate relative to the source.

    2. Depending on where the device is used in the circuit and what voltage will be applied to the gate can help select the part to be used

  10. Maximum DC drain current:

    1. This is the max. current a device can withstand indefinitely given adequate cooling.

    2. This rating may be inaccurate since depending on the Vds, the device may only be able to conduct a small fraction of the current before failure.

    3. The only way to be sure that the device can withstand the desired current is to refer to the safe operating area curve in the device’s datasheet (sample shown below)

  11. Body Diode

    1. IS - tolerable continuous current (A)

    2. ISM - tolerable max (pulse) current (A)

    3. VSD - max source-drain voltage (V)

    4. Switching behavior of MOSFET (each value is for the specified test condition)

      1. trr - reverse recovery time (s)

      2. QRM - max reverse charge (C)

      3. IRM - max reverse current (A)

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