You can still do that with MOSFETS - look up the 'h-bridge'.
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I bought a new switch to replace the LH1505 to try out. I CAN'T figure out why the COM & NO pins connect when I apply power to the either/or. It doesn't matter what I do with the IN (digital control). What am I doing wrong?
http://www.ti.com/lit/ds/symlink/ts12a44514.pdf
http://www.ti.com/lit/ds/symlink/ts12a44514.pdf
So I bought (what I think is) a more efficient regulator. However, I can't figure out how to wire it to get 3.3 volts. I do not have an inductor; is it necessary? Input is 5 volts. Please help.
http://www.ti.com/lit/ds/slvsbk5/slvsbk5.pdf
Uh, yes. It is a switch mode regulator and the inductor is a critical part of the circuit.
It is a fixed regulator, wire it exactly as in the datasheet, and you will get 3.3V.
Bob
davenn
Moderator
as Bob said wire it up per the data sheet. you are missing a bunch of components......
2 resistors, 4 capacitors, a special diode, and the inductor ..... you MUST use all the correct parts and their values else it wont work
Indeed - the datasheet tells you everything you need to know about using the device - how to connect it, how to calculate the component values etc.
You can also 'cheat' and Google the device and search the 'image' results for examples of working circuits others have built. Indeed there are members on here who have attempted the very same:
https://www.electronicspoint.com/threads/1st-buck-converter-design-help-advice.280000/
Ok, now I'm terrified! Although I'm sure this circuit seems very simple for most you on this forum, it's very difficult for me. Is there a more simple device (other than an inefficient linear regulator) that will get me down to 3.3 volts, or am I going to have to venture down this rabbit hole 
?
?There are basic 3.3V modules available on eBay
http://www.ebay.co.uk/itm/DC-5V-to-...191447?hash=item1c57818997:g:oREAAOSw3ydVqeff
OK, they are rated at 5V input but a series diode from your 6V supply will fix that.
http://www.ebay.co.uk/itm/DC-5V-to-...191447?hash=item1c57818997:g:oREAAOSw3ydVqeff
OK, they are rated at 5V input but a series diode from your 6V supply will fix that.
davenn
Moderator
why didn't you continue with the one you posted a datasheet for in post #3 ? I said it looked good
a much lower component count
I have decided to tackle this regulator, but need some help identifying the components needed... The items circled in GREEN are obvious to me. The items circled in RED have me confused.
http://www.ti.com/lit/ds/symlink/tps5403.pdf
My objective is to supply the RF receiver and decoder with 3.3 volts without the use of an inefficient linear regulator.
http://www.ti.com/lit/ds/symlink/tps5403.pdf
My objective is to supply the RF receiver and decoder with 3.3 volts without the use of an inefficient linear regulator.
Imagine you want 3.3V at 100mA. You have a battery which is currently reading as 6.6V.
A linear regulator would have as it's input 6.6V at 100mA, and the excess energy would be expended as heat. This regulator would be 50% efficient at best. As the difference between the input and output voltage changes, the efficiency varies.
A switch mode regulator in the same circumstance will input 50mA at 6.6V and output 3.3V at 100mA. It is (theoretically) 100% efficient.
There switch mode regulator electrical energy in a magnetic field, then converted that magnetic field to electrical energy. This is done in such a way as to change the output voltage in a controlled manner.
A linear regulator has an input current equal to the output current, dissipating the difference between the input and output voltage times the current as heat.
The switch mode regulator has an input power equal to the output power, so if the output voltage is lower than the input voltage, the input current will be lower than the output current. The input current times the input voltage equals the output current times the output voltage.
The inductor, diode, and capacitor in the top right corner of the circuit are three of the necessary four parts of a switch mode regulator (the 4th part is something which switches a current path on and off)
Without those three components on the top right corner, you can't regulate voltage with this chip.
Also remember that there are additional losses which I've not mentioned. Nothing is ever 100% efficient.
A linear regulator would have as it's input 6.6V at 100mA, and the excess energy would be expended as heat. This regulator would be 50% efficient at best. As the difference between the input and output voltage changes, the efficiency varies.
A switch mode regulator in the same circumstance will input 50mA at 6.6V and output 3.3V at 100mA. It is (theoretically) 100% efficient.
There switch mode regulator electrical energy in a magnetic field, then converted that magnetic field to electrical energy. This is done in such a way as to change the output voltage in a controlled manner.
A linear regulator has an input current equal to the output current, dissipating the difference between the input and output voltage times the current as heat.
The switch mode regulator has an input power equal to the output power, so if the output voltage is lower than the input voltage, the input current will be lower than the output current. The input current times the input voltage equals the output current times the output voltage.
The inductor, diode, and capacitor in the top right corner of the circuit are three of the necessary four parts of a switch mode regulator (the 4th part is something which switches a current path on and off)
Without those three components on the top right corner, you can't regulate voltage with this chip.
Also remember that there are additional losses which I've not mentioned. Nothing is ever 100% efficient.
davenn
Moderator
the info is in the datasheet
here's one example from it for calculating the inductor value ....
continued on pages 10 and 11
and following that is info on the capacitor values
On average.
The typical buck converter topology has all the output current coming from the source during the on phase and none during the off phase. So the source would be outputting 100mA when the switch is on and 0 when the switch is off, for an average of 50mA.
Bob
Thank you for this explanation. It clarifies the main difference between the linear and switch mode regulators. Unfortunately (for me
), it doesn't clarify how to solve the equations listed on the datasheet.I'm sure the datasheet explains in detail, how to calculate the inductor and all capacitor values. However, I do not have the skills required to decipher these formulas. I have no idea how to solve these formulas:
Furthermore,
I do not know what type of diode to buy:
I do not even have a basic understanding electronics. I just know my battery only lasts 26 days, and I want it to last longer, AS LONG AS POSSIBLE. I certainly appreciate all of the selfless help I have received on this forum, but I don't know what I don't know
.I found this online. Nice and simple. Thoughts?
Model: TSR 1-2433
http://www.mouser.com/ds/2/687/tsr1-537631.pdf
I think I can handle this one
Model: TSR 1-2433
http://www.mouser.com/ds/2/687/tsr1-537631.pdf
I think I can handle this one
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