# How to make a boost converter circuit

I've seen multiple different explanations on boost converter circuits, these two specifically explaining in very intimate detail how they work, and on how to calculate certain values:

How to design a boost converter? And how to specify the inductor and capacitor values?

Understanding Boost Converter

the basic layout of a boost converter looks like this:

simulate this circuit – Schematic created using CircuitLab

In this example, the 1 volt input would be increased to a higher voltage across the resistor, which would be the load in this case.

## Problem:

I need to switch a 5 volt current on the high side with an NPN switch (for many reasons this is the only switch layout available, no other layout will work as desired), so I need 7 volts to the gate to switch it, however only 5 volts are available. For this I need a boost converter that will convert 5 volts to 7 volts to be able to switch the switch

But, I'm not sure how to calculate any of the values. For example, the solutions in the links I provided use the switching time of the switch, how can I find that? What size inductor and capacitor would I need?

Also as an aside, the thing labelled "L" on the diagram, the inductor, what is it's purpose?

• Before you attempt to design a switching power supply, you need to understand what an inductor fundamentally does. Commented Dec 11, 2015 at 16:25
• I would like you to clarify two things: 1) Is it correct that you have another circuit that is using a transistor for switching, and that you need this circuit to provide the base drive for the other? 2) Are you sure that it is not possible to use an N-channel MOSFET instead of an NPN transistor? The MOSFET would make the drive easier in this case because you don't need as much current, just voltage, which you can create with a simpler capacitor based step-up.
– pipe
Commented Dec 11, 2015 at 16:30
• @pipe I'm sorry, I thought n channel mofsets were npn switches. It is in fact an n-channel mofset that I'm referring to here. NTE490 specifically. Commented Dec 11, 2015 at 16:35
• In that case you don't need anything fancy. If you already have a microcontroller you can take a look at this answer: electronics.stackexchange.com/a/147975/91862. Otherwise there's the very cheap ICL7660 and clones available.
– pipe
Commented Dec 11, 2015 at 16:41
• @pipe that answer's circuit won't work. Commented Dec 11, 2015 at 18:27

The simplest solution would be to use a small, integrated boost IC. For example here is one from TI, but there are lots of other choices from other vendors as well (The component value choices are clearly explained in the datasheet):

TPS61046

However, you mention you need 2V above your 5V rail to switch your FET. Are you sure that you will be able to turn the FET fully on with 2V VGS? Most FETs have a threshold voltage in the 2V region meaning they are just starting to conduct there. You may want to switch the gate with 5V Vgs or a 10V boosted supply.

If you don't need the FET to be on continuously, and you have a defined minimum off time you may be able to use a bootstrap circuit to generate the gate drive voltage. Without knowing more about what you are doing it's impossible to say if a that would work or not. You might start another thread with more details if you don't know how to make a bootstrap work.

Finally, the purpose of the inductor is energy storage. When the switch is on the current in the inductor ramps up according to V=L*di/dt. The output voltage is held up by the output cap and the diode isolates the output from the switch. The energy stored is 1/2*L*I^2. Then when the switch turns off the inductor ramps down, though at this point the voltage across the inductor is in the opposite direction and equal to Vout-Vin. So the inductor provides energy to the output during the off time, allowing the output voltage to rise above the input voltage.

• Thank you very much! I think this will lead me in just the right direction. :) Commented Dec 11, 2015 at 16:32
• So John, this ICU is actually only 0.8 x 1.2 mm, which ironically is a bit too compact. Way too small to work with! If you know of any others off of the top your head that are large enough to at least be soldered to without advanced machinery. If so, thank you, and if not, thank you very much again for your help. Commented Dec 11, 2015 at 18:07
• Here's a part in a SOT-23-5 package, which I find pretty easy to work with manually. ti.com/lit/ds/symlink/lmr64010.pdf Commented Dec 11, 2015 at 18:18

Also as an aside, the thing labelled "L" on the diagram, the inductor, what is it's purpose?

If you have an elastic band stretched across an opening and you pull it down in the middle (to ground) then release it, said elastic band responds by rapidly rising and if you have your hand in the way then you can get a slightly painful little recoil slap. Here's a nice picture to consider: -

You can fire the little object attached to the rubber band quite a distance.

Now that analogy isn't precisely what happens with the inductor but it's near enough to make use of.

So, instead of allowing the elastic band to freely recoil (and waste all the energy you have put into it), imagine you mechanically harvested that recoil to push a little mass/object a little bit higher each time you released the elastic band.

You'd need the mechanical equivalent of a diode so that when the elastic band was pulled down you didn't return the object/mass to ground. That wouldn't be too hard to build but you don't need to build it - you just need to understand the analogy.

So, to get 7V from 5V you need to turn on the transistor for long enough to build up a certain current - that current defines the energy stored in the coil and when that energy is released via the diode and into the capacitor and load, it's enough energy to keep it at 7V and the cap is big enough so that the 7V doesn't droop too much when the inductor is being pulled to ground.

However, the difficulty arises when you try and control the output voltage to a precise value - it is highly load dependent and highly input voltage dependent and so normally what happens is that an op-amp control loop defines the duty cycle of the inductor to prevent too big an output voltage being generated.

• Thank you for this info, I'm new to electrical engineering and this may greatly help me in the near future. Commented Dec 11, 2015 at 16:33
• I think that example is more analogous to a capacitor rather than an inductor. A more appropriate mechanical equivelant of inductance is inertia, as for example the hydraulic ram pump is the water version of a boost converter, and the inertia of the water performs the same function of the inductor in the electrical circuit. Commented Dec 11, 2015 at 18:15
• @whatsisname - it's an analogy and a capacitor can certainly be modelled as a flyweel possessing inertia. They are interchangeable analogies. Commented Dec 11, 2015 at 18:18
• Electricity doesn't behave quite like anything else, so analogies always break down at some point. The key is understanding that energy is being stored in the magnetic field, and later that same energy is released in a slightly different form. Commented Dec 11, 2015 at 21:45
• I've used a water under pressure flowing through a rubber tube analog. The tube balloons under pressure, resists flow, stores and releases energy, ... . The model isn't perfect (of course). Commented Mar 5, 2020 at 1:39

May be this is not a direct answer but it gives a simple explanation, using old time experience in boost and buck converters using transformers.

BOOST

BUCK

• This is just regular old transformer usage, boost and buck converters exploit the transient behavior of inductors rather than their steady states. Commented Dec 11, 2015 at 18:21
• Or a variable autotransformer effectively can do both. But only for AC input & AC output; OP is asking about DC to DC converter. Commented Dec 11, 2015 at 21:49