How make a dual +-12V supply from a 24V SMPS











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I'm trying to power a home-made load cell transmitter using a 24V single SMPS. I need to make +12, 0 and -12 Volts that are capable of 50mA. I wish to power multiple channels of opamps and bridges.



I don't have much budget and availability of components in India.



I have an idea to use 1 LM7812 an 1 LM7912(negative) linear voltage regulators and a voltage divider setup to do this as per the circuit below.





schematic





simulate this circuit – Schematic created using CircuitLab



Would this work? I've modified it from the suggestions and articles elsewhere.



Somebody suggested me one other circuit but I am concerned about the current capabilities of the opamp.





schematic





simulate this circuit



Would this work? If yes, please suggest suitable op-amp.



Are there any other techniques that would do the job economically?










share|improve this question
























  • Think about what will happen if you have mismatched loads between the rails.
    – winny
    yesterday










  • @winny That's what I am worried about.
    – Ohbhatt
    yesterday










  • How much current do you need? I have made such a contrapment for an audio circuit to prevent uneven clipping using an opamp and even divider like yours, but transistor+resisor buffered on the output. Wasted a lot of power and there are easier solutions. In your case, I would go for two switchmode converters or one isolated one.
    – winny
    yesterday






  • 3




    You mention you need to be able to supply 50mA of current. But I guess this is mainly through the +12 and -12 rails (e.g. powering dual-supply opamps). What exactly do you have to supply through the 0V rail? If the 0V rail simply serves as a reference and only goes to some opamp inputs or high-valued resistors, it means your current needs for the 0V rail are much much lower than 50mA, and the solution #2 is perfectly valid.
    – dim
    yesterday










  • Btw, both farnell.in and mouser.in ship in India. You would find pretty much any component on these(albeit a bit pricey ). Another option is ebay.com , but these ship from China and have quite long delivery times.
    – Tejas Kale
    3 hours ago















up vote
12
down vote

favorite
4












I'm trying to power a home-made load cell transmitter using a 24V single SMPS. I need to make +12, 0 and -12 Volts that are capable of 50mA. I wish to power multiple channels of opamps and bridges.



I don't have much budget and availability of components in India.



I have an idea to use 1 LM7812 an 1 LM7912(negative) linear voltage regulators and a voltage divider setup to do this as per the circuit below.





schematic





simulate this circuit – Schematic created using CircuitLab



Would this work? I've modified it from the suggestions and articles elsewhere.



Somebody suggested me one other circuit but I am concerned about the current capabilities of the opamp.





schematic





simulate this circuit



Would this work? If yes, please suggest suitable op-amp.



Are there any other techniques that would do the job economically?










share|improve this question
























  • Think about what will happen if you have mismatched loads between the rails.
    – winny
    yesterday










  • @winny That's what I am worried about.
    – Ohbhatt
    yesterday










  • How much current do you need? I have made such a contrapment for an audio circuit to prevent uneven clipping using an opamp and even divider like yours, but transistor+resisor buffered on the output. Wasted a lot of power and there are easier solutions. In your case, I would go for two switchmode converters or one isolated one.
    – winny
    yesterday






  • 3




    You mention you need to be able to supply 50mA of current. But I guess this is mainly through the +12 and -12 rails (e.g. powering dual-supply opamps). What exactly do you have to supply through the 0V rail? If the 0V rail simply serves as a reference and only goes to some opamp inputs or high-valued resistors, it means your current needs for the 0V rail are much much lower than 50mA, and the solution #2 is perfectly valid.
    – dim
    yesterday










  • Btw, both farnell.in and mouser.in ship in India. You would find pretty much any component on these(albeit a bit pricey ). Another option is ebay.com , but these ship from China and have quite long delivery times.
    – Tejas Kale
    3 hours ago













up vote
12
down vote

favorite
4









up vote
12
down vote

favorite
4






4





I'm trying to power a home-made load cell transmitter using a 24V single SMPS. I need to make +12, 0 and -12 Volts that are capable of 50mA. I wish to power multiple channels of opamps and bridges.



I don't have much budget and availability of components in India.



I have an idea to use 1 LM7812 an 1 LM7912(negative) linear voltage regulators and a voltage divider setup to do this as per the circuit below.





schematic





simulate this circuit – Schematic created using CircuitLab



Would this work? I've modified it from the suggestions and articles elsewhere.



Somebody suggested me one other circuit but I am concerned about the current capabilities of the opamp.





schematic





simulate this circuit



Would this work? If yes, please suggest suitable op-amp.



Are there any other techniques that would do the job economically?










share|improve this question















I'm trying to power a home-made load cell transmitter using a 24V single SMPS. I need to make +12, 0 and -12 Volts that are capable of 50mA. I wish to power multiple channels of opamps and bridges.



I don't have much budget and availability of components in India.



I have an idea to use 1 LM7812 an 1 LM7912(negative) linear voltage regulators and a voltage divider setup to do this as per the circuit below.





schematic





simulate this circuit – Schematic created using CircuitLab



Would this work? I've modified it from the suggestions and articles elsewhere.



Somebody suggested me one other circuit but I am concerned about the current capabilities of the opamp.





schematic





simulate this circuit



Would this work? If yes, please suggest suitable op-amp.



Are there any other techniques that would do the job economically?







op-amp voltage-regulator voltage-divider 24v virtual-ground






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edited yesterday









JRE

20k43766




20k43766










asked yesterday









Ohbhatt

708




708












  • Think about what will happen if you have mismatched loads between the rails.
    – winny
    yesterday










  • @winny That's what I am worried about.
    – Ohbhatt
    yesterday










  • How much current do you need? I have made such a contrapment for an audio circuit to prevent uneven clipping using an opamp and even divider like yours, but transistor+resisor buffered on the output. Wasted a lot of power and there are easier solutions. In your case, I would go for two switchmode converters or one isolated one.
    – winny
    yesterday






  • 3




    You mention you need to be able to supply 50mA of current. But I guess this is mainly through the +12 and -12 rails (e.g. powering dual-supply opamps). What exactly do you have to supply through the 0V rail? If the 0V rail simply serves as a reference and only goes to some opamp inputs or high-valued resistors, it means your current needs for the 0V rail are much much lower than 50mA, and the solution #2 is perfectly valid.
    – dim
    yesterday










  • Btw, both farnell.in and mouser.in ship in India. You would find pretty much any component on these(albeit a bit pricey ). Another option is ebay.com , but these ship from China and have quite long delivery times.
    – Tejas Kale
    3 hours ago


















  • Think about what will happen if you have mismatched loads between the rails.
    – winny
    yesterday










  • @winny That's what I am worried about.
    – Ohbhatt
    yesterday










  • How much current do you need? I have made such a contrapment for an audio circuit to prevent uneven clipping using an opamp and even divider like yours, but transistor+resisor buffered on the output. Wasted a lot of power and there are easier solutions. In your case, I would go for two switchmode converters or one isolated one.
    – winny
    yesterday






  • 3




    You mention you need to be able to supply 50mA of current. But I guess this is mainly through the +12 and -12 rails (e.g. powering dual-supply opamps). What exactly do you have to supply through the 0V rail? If the 0V rail simply serves as a reference and only goes to some opamp inputs or high-valued resistors, it means your current needs for the 0V rail are much much lower than 50mA, and the solution #2 is perfectly valid.
    – dim
    yesterday










  • Btw, both farnell.in and mouser.in ship in India. You would find pretty much any component on these(albeit a bit pricey ). Another option is ebay.com , but these ship from China and have quite long delivery times.
    – Tejas Kale
    3 hours ago
















Think about what will happen if you have mismatched loads between the rails.
– winny
yesterday




Think about what will happen if you have mismatched loads between the rails.
– winny
yesterday












@winny That's what I am worried about.
– Ohbhatt
yesterday




@winny That's what I am worried about.
– Ohbhatt
yesterday












How much current do you need? I have made such a contrapment for an audio circuit to prevent uneven clipping using an opamp and even divider like yours, but transistor+resisor buffered on the output. Wasted a lot of power and there are easier solutions. In your case, I would go for two switchmode converters or one isolated one.
– winny
yesterday




How much current do you need? I have made such a contrapment for an audio circuit to prevent uneven clipping using an opamp and even divider like yours, but transistor+resisor buffered on the output. Wasted a lot of power and there are easier solutions. In your case, I would go for two switchmode converters or one isolated one.
– winny
yesterday




3




3




You mention you need to be able to supply 50mA of current. But I guess this is mainly through the +12 and -12 rails (e.g. powering dual-supply opamps). What exactly do you have to supply through the 0V rail? If the 0V rail simply serves as a reference and only goes to some opamp inputs or high-valued resistors, it means your current needs for the 0V rail are much much lower than 50mA, and the solution #2 is perfectly valid.
– dim
yesterday




You mention you need to be able to supply 50mA of current. But I guess this is mainly through the +12 and -12 rails (e.g. powering dual-supply opamps). What exactly do you have to supply through the 0V rail? If the 0V rail simply serves as a reference and only goes to some opamp inputs or high-valued resistors, it means your current needs for the 0V rail are much much lower than 50mA, and the solution #2 is perfectly valid.
– dim
yesterday












Btw, both farnell.in and mouser.in ship in India. You would find pretty much any component on these(albeit a bit pricey ). Another option is ebay.com , but these ship from China and have quite long delivery times.
– Tejas Kale
3 hours ago




Btw, both farnell.in and mouser.in ship in India. You would find pretty much any component on these(albeit a bit pricey ). Another option is ebay.com , but these ship from China and have quite long delivery times.
– Tejas Kale
3 hours ago










7 Answers
7






active

oldest

votes

















up vote
13
down vote



accepted










You first idea will not work at all.





Your second idea will work, but many OP-Amps aren't going to deliver more than a few mA on their output, which limits the current your circuit may draw from the virtual ground. There are Power-OP-Amps available which may deliver up to a few ampere, but if you cannot get your hands on one, you can use a PNP/NPN transistor pair to increase the output current:





schematic





simulate this circuit – Schematic created using CircuitLab



The OP-Amp will take care of stabilizing the output so it matches the voltage set by the input voltage divider. Take care of capacitive loads, as Spehro noted in his answer, though.






share|improve this answer























  • can you please suggest a Transistor suitable for 50 or 100mA.
    – Ohbhatt
    yesterday






  • 1




    You have to look for the packages. For 100mA, each transistor had to dissipate 100mA*12V=1.2W, that's the limiting factor. Small signal transistors in TO-92 packages are typically limited to 500mW. There are exceptions as the SS8050/SS8550 pair from Fairchild which can dissipate 2W each. A far more conservative pair (also better available) would be BD233/BD234, BD235/BD236 or BD237/BD238. (Use transistors meant for audio applications, they are rated for linear region operation, as needed here.) Transistors in TO220 packages are overkill for your application.
    – Janka
    yesterday












  • Okay. I will take a look at that. Thank you for the time.
    – Ohbhatt
    yesterday










  • Would 2n2222(NPN) and 2N2907(PNP) Work for this? I am unable to avail any of the above pairs at acceptable cost or separately(I have to purchase in bulk otherwise). I crosschecked the power will not be above 500mW in any case between the reference and either + and - rails.
    – Ohbhatt
    13 hours ago










  • The 2N2222 can only dissipate 500mW, that's good for 41mA@12V. The 2N2907 can only dissipate 625mW, good for 52mA@12V. In general, transistors starting with BD are what you want (the 2N… prefix unfortunately gives no hint.)
    – Janka
    12 hours ago




















up vote
7
down vote













You'd be better off using two 12V supplies, but if you insist...



#1 won't work.



#2 (given the very limited information you have supplied) might require the op-amp to dissipate as much as 600mW and stability would likely be an issue with capacitive loads. There are dedicated rail splitter chips which take stability seriously but they are not jellybean parts and, for example, the TLE2426 cannot handle the dissipation or current involved.



I suggest something more like this (assuming you have power to spare on your 12V supply:



enter image description here



This uses a ubiquitous TL431 shunt regulator and boosts it with a generic PNP power transistor.



The combination is like a precision power zener. Or just use a zener as below. Set Vo = 12V.



Then use this circuit:





schematic





simulate this circuit – Schematic created using CircuitLab



Note that if you excessively load the GND to -V the +V to GND voltage will increase to as much as 24V. Usually that's acceptable but take care about capacitor voltage rating and so on. You can add a higher voltage zener (say 14V) across R1 as a preventative measure.
R1 will dissipate less than 1W, under normal conditions, but the zener could dissipate as much as 1.3W if 50mA flows from +V to GND and there is no corresponding current from GND to -V.



You could use two 6.2V 1W zeners in series, for example. Keep the leads short, attach them to some PCB area and keep them apart so they run cooler.






share|improve this answer























  • I have to keep minimal power consumption and I cant afford any change in the voltage. Thanks for the help though.
    – Ohbhatt
    yesterday






  • 1




    I wouldn't use a regulator approach to generating the virtual ground at all -- it's going to have problems either sourcing or sinking appropriate currents.
    – ThreePhaseEel
    22 hours ago


















up vote
5
down vote













Given your desire for as low power as possible, and my realization that this common problem is seldom approached this way. I came up with a self-oscillating switching solution just for the fun of it.



As with any switcher, single-tone emissions/ripple have to be considered (around 20kHz with these values). But if there is any significant ground current, I doubt you can be much more efficient (a more formal switcher with a separate oscillator can be made more efficient and could use a single inductor, but it would require more parts).





schematic





simulate this circuit – Schematic created using CircuitLab



It is basically a relaxation oscillator that modulates the average current through L1 so that it oscillates around the required ground current. M1 and M2 are switched on and off relatively quickly (some acceleration capacitors would help with efficiency) and C12 provides positive feedback so that the opamp/comparator saturates on crossing the threshold (otherwise the load would damp the oscillator and it would become a linear regulator instead).



L3, C10, and C11 are there to filter the ripple and to isolate the oscillation from the load, so as to avoid dampening it too much. C10, and C11 also do double-duty as the regulator input capacitance. Excess energy in L1 and L2 would be returned to the required rail and stored in them. M1 and M2 source-drain diodes are conducting in this design.



R3,R4,R5, and R6 are chosen so as to keep M1 and M2 below threshold when there is no ground current. Unfortunately this also reduces the overall gain of the oscillator loop.



I have not done a very careful analysis of all of the implications of this design (particularly because of it being self-oscillating), so overall stability considerations on load changes might be an issue.



I don't think there are ICs for this type of configuration, which unnecessarily increases the part count and the design constraints. The only ones I know of are the DDR memory termination voltage regulators, but those are intended to work at very low voltages.






share|improve this answer























  • +1, this is ingenious. But I think the reason it isn't too common is circuits which need split ground are most times for audio applications and we would certainly hear the chime.
    – Janka
    yesterday








  • 1




    Making a 400kHz-1MHz switcher is possible. You would not hear that at all!! And after all ground is the reference, it will be the rails that are moving... I am normally dealing with applications in which even 1µV of noise in high-impedance traces is an issue, we use switchers all over the place. Including driving variable analog power lines that run under those high-impedance traces. All it needs is good filtering, our only issues have arisen when the switcher control algorithms skip-beats and produce low-frequency components.
    – Edgar Brown
    yesterday










  • Yes, exactly the latter was my concern. What happens when the ground current changes direction.
    – Janka
    yesterday






  • 1




    @Janka In this architecture, assuming that it is fully stable, nothing of consequence will happen. The excess current will simply be steered via a MOSFET diode to the rail that is supplying it. Ideally zero waste power.
    – Edgar Brown
    yesterday






  • 1




    @Janka Oh, and regarding the tones, the issue only happened when during a design modification for an updated version of the product someone did not pay too much attention to a trace and made a long loop with it, which interacted with loops in the high-impedance traces. Even then the noise was barely above detection in the 2µV range. We fixed it by improving the control algorithm. In this architecture the switcher never has to go silent, small alternating pulses in both directions can ensure that. With this design that could be problematic to achieve, but a separate oscillator would fix that..
    – Edgar Brown
    yesterday


















up vote
4
down vote













The regulators won’t work. You have zero dropout allocated to them and your ground impedance is excessive.



The op amp is a better option, but it all depends on how much current you have going through ground. If the current is low enough you can just use a resistor divider with a couple of capacitors in parallel, if it is high you would need a hefty op amp.



You have a couple more options:




  1. You could use two zeners with series resistors to reduce ground impedance

  2. You could put together a class AB source follower with a few resistors and two transistors (basically what the op-amp is doing but with higher impedance)

  3. If your ground current has a well-defined and consistent direction, you can use a positive or negative 12V regulator or even a transistor off one of the rails (making sure to put a bypass diode).


But regardless of what you do, any ground current will result in wasted power (unless you figure out how to design a ground-switcher regulator of course).






share|improve this answer





















  • Thank you for the observation.
    – Ohbhatt
    yesterday


















up vote
4
down vote













If your 24 V is well regulated you could just use a 7812 to create a mid point and call that your 0 volt rail.





schematic





simulate this circuit – Schematic created using CircuitLab



This will only work if the 24 V is independent of whatever you're powering, and as per Edgar Brown's comment, positive linear regulators like the 7812 can't sink current.






share|improve this answer























  • That is a fantastic solution. I don't have to invest in any expensive parts. But I still have to test this circuit to verify.
    – Ohbhatt
    yesterday






  • 4




    This will only work if your ground current is positive (it exits the regulator) normal regulators don’t sink current.
    – Edgar Brown
    yesterday










  • That's a very valid point, thanks, @EdgarBrown, I've edited the answer.
    – Colin
    yesterday








  • 3




    @EdgarBrown Instead of a trusty 7812 you can use an integrated switching regulator that will generally tolerate "reverse current", they are a little more money, but same simple implementation. I have used this in a design, granted in my case most of the system was running on the 24V rail, with only a small subset of components running off the virtual ground. In any case, this becomes a matter of component selection, and 1/2/3A switching regulators can be found with bidrectional current capability, the design is solid, but the BOM may be hard to find or expensive.
    – crasic
    yesterday








  • 1




    @Ohbhatt No, that does not eliminate any change. Imagine if you connected a resistor between +12V and 0V, the regulator would not handle that because the current would be trying to go into the regulator. But a resistor between 0V and -12V would be fine. That's why it depends on your circuit design.
    – immibis
    yesterday




















up vote
2
down vote













I think NJM4556A would work



you can draw current from negative and positive rails but there difference not to exceed the OP amp output current.



Note: I'm not experienced, i suggest you to read the following post



EEVBLOG - my-negative-voltage-rail-doesnt-work






share|improve this answer





















  • That is a good idea. I will took into that.
    – Ohbhatt
    yesterday


















up vote
0
down vote













There are many low-cost methods. But switching method may help you with a minimum component that available everywhere.



you can use a flyback converter with a minimum circuit:



Edited: The main circuit:
mix circuit
Ref: a mix of two links (http://uzzors2k.4hv.org/index.phppage=flybacktransformerdrivers, https://wiki.analog.com/university/courses/electronics/text/chapter-6)



Component list:




  • Zener diode


  • 555 IC


  • Mosfet


  • A toroid, the transformer can be made with wire and a toroid core


  • Diode in output


  • some capacitor


  • some resistor


  • some wire



Benefits:




  • you can generate any voltage in output even bigger than your first voltage


  • these components are available everywhere


  • you can generate any voltage even isolated voltage


  • you can increase your power by changing the Mosfet and selecting a bigger toroid.



The main references:



http://uzzors2k.4hv.org/index.php?page=flybacktransformerdrivers
enter image description here



Additionally, you need a Zener diode for 12-15volt and a 555 IC.( your coil feed with 24Volt but for 555, you should generate a 12-volt power with a Zener diode).



in the output, you need a diode with a capacitor.
link: https://wiki.analog.com/university/courses/electronics/text/chapter-6
enter image description here



It is dual polarity Full-wave rectifier using a center tapped transformer and 4 diodes






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    7 Answers
    7






    active

    oldest

    votes








    7 Answers
    7






    active

    oldest

    votes









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    oldest

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    active

    oldest

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    up vote
    13
    down vote



    accepted










    You first idea will not work at all.





    Your second idea will work, but many OP-Amps aren't going to deliver more than a few mA on their output, which limits the current your circuit may draw from the virtual ground. There are Power-OP-Amps available which may deliver up to a few ampere, but if you cannot get your hands on one, you can use a PNP/NPN transistor pair to increase the output current:





    schematic





    simulate this circuit – Schematic created using CircuitLab



    The OP-Amp will take care of stabilizing the output so it matches the voltage set by the input voltage divider. Take care of capacitive loads, as Spehro noted in his answer, though.






    share|improve this answer























    • can you please suggest a Transistor suitable for 50 or 100mA.
      – Ohbhatt
      yesterday






    • 1




      You have to look for the packages. For 100mA, each transistor had to dissipate 100mA*12V=1.2W, that's the limiting factor. Small signal transistors in TO-92 packages are typically limited to 500mW. There are exceptions as the SS8050/SS8550 pair from Fairchild which can dissipate 2W each. A far more conservative pair (also better available) would be BD233/BD234, BD235/BD236 or BD237/BD238. (Use transistors meant for audio applications, they are rated for linear region operation, as needed here.) Transistors in TO220 packages are overkill for your application.
      – Janka
      yesterday












    • Okay. I will take a look at that. Thank you for the time.
      – Ohbhatt
      yesterday










    • Would 2n2222(NPN) and 2N2907(PNP) Work for this? I am unable to avail any of the above pairs at acceptable cost or separately(I have to purchase in bulk otherwise). I crosschecked the power will not be above 500mW in any case between the reference and either + and - rails.
      – Ohbhatt
      13 hours ago










    • The 2N2222 can only dissipate 500mW, that's good for 41mA@12V. The 2N2907 can only dissipate 625mW, good for 52mA@12V. In general, transistors starting with BD are what you want (the 2N… prefix unfortunately gives no hint.)
      – Janka
      12 hours ago

















    up vote
    13
    down vote



    accepted










    You first idea will not work at all.





    Your second idea will work, but many OP-Amps aren't going to deliver more than a few mA on their output, which limits the current your circuit may draw from the virtual ground. There are Power-OP-Amps available which may deliver up to a few ampere, but if you cannot get your hands on one, you can use a PNP/NPN transistor pair to increase the output current:





    schematic





    simulate this circuit – Schematic created using CircuitLab



    The OP-Amp will take care of stabilizing the output so it matches the voltage set by the input voltage divider. Take care of capacitive loads, as Spehro noted in his answer, though.






    share|improve this answer























    • can you please suggest a Transistor suitable for 50 or 100mA.
      – Ohbhatt
      yesterday






    • 1




      You have to look for the packages. For 100mA, each transistor had to dissipate 100mA*12V=1.2W, that's the limiting factor. Small signal transistors in TO-92 packages are typically limited to 500mW. There are exceptions as the SS8050/SS8550 pair from Fairchild which can dissipate 2W each. A far more conservative pair (also better available) would be BD233/BD234, BD235/BD236 or BD237/BD238. (Use transistors meant for audio applications, they are rated for linear region operation, as needed here.) Transistors in TO220 packages are overkill for your application.
      – Janka
      yesterday












    • Okay. I will take a look at that. Thank you for the time.
      – Ohbhatt
      yesterday










    • Would 2n2222(NPN) and 2N2907(PNP) Work for this? I am unable to avail any of the above pairs at acceptable cost or separately(I have to purchase in bulk otherwise). I crosschecked the power will not be above 500mW in any case between the reference and either + and - rails.
      – Ohbhatt
      13 hours ago










    • The 2N2222 can only dissipate 500mW, that's good for 41mA@12V. The 2N2907 can only dissipate 625mW, good for 52mA@12V. In general, transistors starting with BD are what you want (the 2N… prefix unfortunately gives no hint.)
      – Janka
      12 hours ago















    up vote
    13
    down vote



    accepted







    up vote
    13
    down vote



    accepted






    You first idea will not work at all.





    Your second idea will work, but many OP-Amps aren't going to deliver more than a few mA on their output, which limits the current your circuit may draw from the virtual ground. There are Power-OP-Amps available which may deliver up to a few ampere, but if you cannot get your hands on one, you can use a PNP/NPN transistor pair to increase the output current:





    schematic





    simulate this circuit – Schematic created using CircuitLab



    The OP-Amp will take care of stabilizing the output so it matches the voltage set by the input voltage divider. Take care of capacitive loads, as Spehro noted in his answer, though.






    share|improve this answer














    You first idea will not work at all.





    Your second idea will work, but many OP-Amps aren't going to deliver more than a few mA on their output, which limits the current your circuit may draw from the virtual ground. There are Power-OP-Amps available which may deliver up to a few ampere, but if you cannot get your hands on one, you can use a PNP/NPN transistor pair to increase the output current:





    schematic





    simulate this circuit – Schematic created using CircuitLab



    The OP-Amp will take care of stabilizing the output so it matches the voltage set by the input voltage divider. Take care of capacitive loads, as Spehro noted in his answer, though.







    share|improve this answer














    share|improve this answer



    share|improve this answer








    edited yesterday

























    answered yesterday









    Janka

    7,9991820




    7,9991820












    • can you please suggest a Transistor suitable for 50 or 100mA.
      – Ohbhatt
      yesterday






    • 1




      You have to look for the packages. For 100mA, each transistor had to dissipate 100mA*12V=1.2W, that's the limiting factor. Small signal transistors in TO-92 packages are typically limited to 500mW. There are exceptions as the SS8050/SS8550 pair from Fairchild which can dissipate 2W each. A far more conservative pair (also better available) would be BD233/BD234, BD235/BD236 or BD237/BD238. (Use transistors meant for audio applications, they are rated for linear region operation, as needed here.) Transistors in TO220 packages are overkill for your application.
      – Janka
      yesterday












    • Okay. I will take a look at that. Thank you for the time.
      – Ohbhatt
      yesterday










    • Would 2n2222(NPN) and 2N2907(PNP) Work for this? I am unable to avail any of the above pairs at acceptable cost or separately(I have to purchase in bulk otherwise). I crosschecked the power will not be above 500mW in any case between the reference and either + and - rails.
      – Ohbhatt
      13 hours ago










    • The 2N2222 can only dissipate 500mW, that's good for 41mA@12V. The 2N2907 can only dissipate 625mW, good for 52mA@12V. In general, transistors starting with BD are what you want (the 2N… prefix unfortunately gives no hint.)
      – Janka
      12 hours ago




















    • can you please suggest a Transistor suitable for 50 or 100mA.
      – Ohbhatt
      yesterday






    • 1




      You have to look for the packages. For 100mA, each transistor had to dissipate 100mA*12V=1.2W, that's the limiting factor. Small signal transistors in TO-92 packages are typically limited to 500mW. There are exceptions as the SS8050/SS8550 pair from Fairchild which can dissipate 2W each. A far more conservative pair (also better available) would be BD233/BD234, BD235/BD236 or BD237/BD238. (Use transistors meant for audio applications, they are rated for linear region operation, as needed here.) Transistors in TO220 packages are overkill for your application.
      – Janka
      yesterday












    • Okay. I will take a look at that. Thank you for the time.
      – Ohbhatt
      yesterday










    • Would 2n2222(NPN) and 2N2907(PNP) Work for this? I am unable to avail any of the above pairs at acceptable cost or separately(I have to purchase in bulk otherwise). I crosschecked the power will not be above 500mW in any case between the reference and either + and - rails.
      – Ohbhatt
      13 hours ago










    • The 2N2222 can only dissipate 500mW, that's good for 41mA@12V. The 2N2907 can only dissipate 625mW, good for 52mA@12V. In general, transistors starting with BD are what you want (the 2N… prefix unfortunately gives no hint.)
      – Janka
      12 hours ago


















    can you please suggest a Transistor suitable for 50 or 100mA.
    – Ohbhatt
    yesterday




    can you please suggest a Transistor suitable for 50 or 100mA.
    – Ohbhatt
    yesterday




    1




    1




    You have to look for the packages. For 100mA, each transistor had to dissipate 100mA*12V=1.2W, that's the limiting factor. Small signal transistors in TO-92 packages are typically limited to 500mW. There are exceptions as the SS8050/SS8550 pair from Fairchild which can dissipate 2W each. A far more conservative pair (also better available) would be BD233/BD234, BD235/BD236 or BD237/BD238. (Use transistors meant for audio applications, they are rated for linear region operation, as needed here.) Transistors in TO220 packages are overkill for your application.
    – Janka
    yesterday






    You have to look for the packages. For 100mA, each transistor had to dissipate 100mA*12V=1.2W, that's the limiting factor. Small signal transistors in TO-92 packages are typically limited to 500mW. There are exceptions as the SS8050/SS8550 pair from Fairchild which can dissipate 2W each. A far more conservative pair (also better available) would be BD233/BD234, BD235/BD236 or BD237/BD238. (Use transistors meant for audio applications, they are rated for linear region operation, as needed here.) Transistors in TO220 packages are overkill for your application.
    – Janka
    yesterday














    Okay. I will take a look at that. Thank you for the time.
    – Ohbhatt
    yesterday




    Okay. I will take a look at that. Thank you for the time.
    – Ohbhatt
    yesterday












    Would 2n2222(NPN) and 2N2907(PNP) Work for this? I am unable to avail any of the above pairs at acceptable cost or separately(I have to purchase in bulk otherwise). I crosschecked the power will not be above 500mW in any case between the reference and either + and - rails.
    – Ohbhatt
    13 hours ago




    Would 2n2222(NPN) and 2N2907(PNP) Work for this? I am unable to avail any of the above pairs at acceptable cost or separately(I have to purchase in bulk otherwise). I crosschecked the power will not be above 500mW in any case between the reference and either + and - rails.
    – Ohbhatt
    13 hours ago












    The 2N2222 can only dissipate 500mW, that's good for 41mA@12V. The 2N2907 can only dissipate 625mW, good for 52mA@12V. In general, transistors starting with BD are what you want (the 2N… prefix unfortunately gives no hint.)
    – Janka
    12 hours ago






    The 2N2222 can only dissipate 500mW, that's good for 41mA@12V. The 2N2907 can only dissipate 625mW, good for 52mA@12V. In general, transistors starting with BD are what you want (the 2N… prefix unfortunately gives no hint.)
    – Janka
    12 hours ago














    up vote
    7
    down vote













    You'd be better off using two 12V supplies, but if you insist...



    #1 won't work.



    #2 (given the very limited information you have supplied) might require the op-amp to dissipate as much as 600mW and stability would likely be an issue with capacitive loads. There are dedicated rail splitter chips which take stability seriously but they are not jellybean parts and, for example, the TLE2426 cannot handle the dissipation or current involved.



    I suggest something more like this (assuming you have power to spare on your 12V supply:



    enter image description here



    This uses a ubiquitous TL431 shunt regulator and boosts it with a generic PNP power transistor.



    The combination is like a precision power zener. Or just use a zener as below. Set Vo = 12V.



    Then use this circuit:





    schematic





    simulate this circuit – Schematic created using CircuitLab



    Note that if you excessively load the GND to -V the +V to GND voltage will increase to as much as 24V. Usually that's acceptable but take care about capacitor voltage rating and so on. You can add a higher voltage zener (say 14V) across R1 as a preventative measure.
    R1 will dissipate less than 1W, under normal conditions, but the zener could dissipate as much as 1.3W if 50mA flows from +V to GND and there is no corresponding current from GND to -V.



    You could use two 6.2V 1W zeners in series, for example. Keep the leads short, attach them to some PCB area and keep them apart so they run cooler.






    share|improve this answer























    • I have to keep minimal power consumption and I cant afford any change in the voltage. Thanks for the help though.
      – Ohbhatt
      yesterday






    • 1




      I wouldn't use a regulator approach to generating the virtual ground at all -- it's going to have problems either sourcing or sinking appropriate currents.
      – ThreePhaseEel
      22 hours ago















    up vote
    7
    down vote













    You'd be better off using two 12V supplies, but if you insist...



    #1 won't work.



    #2 (given the very limited information you have supplied) might require the op-amp to dissipate as much as 600mW and stability would likely be an issue with capacitive loads. There are dedicated rail splitter chips which take stability seriously but they are not jellybean parts and, for example, the TLE2426 cannot handle the dissipation or current involved.



    I suggest something more like this (assuming you have power to spare on your 12V supply:



    enter image description here



    This uses a ubiquitous TL431 shunt regulator and boosts it with a generic PNP power transistor.



    The combination is like a precision power zener. Or just use a zener as below. Set Vo = 12V.



    Then use this circuit:





    schematic





    simulate this circuit – Schematic created using CircuitLab



    Note that if you excessively load the GND to -V the +V to GND voltage will increase to as much as 24V. Usually that's acceptable but take care about capacitor voltage rating and so on. You can add a higher voltage zener (say 14V) across R1 as a preventative measure.
    R1 will dissipate less than 1W, under normal conditions, but the zener could dissipate as much as 1.3W if 50mA flows from +V to GND and there is no corresponding current from GND to -V.



    You could use two 6.2V 1W zeners in series, for example. Keep the leads short, attach them to some PCB area and keep them apart so they run cooler.






    share|improve this answer























    • I have to keep minimal power consumption and I cant afford any change in the voltage. Thanks for the help though.
      – Ohbhatt
      yesterday






    • 1




      I wouldn't use a regulator approach to generating the virtual ground at all -- it's going to have problems either sourcing or sinking appropriate currents.
      – ThreePhaseEel
      22 hours ago













    up vote
    7
    down vote










    up vote
    7
    down vote









    You'd be better off using two 12V supplies, but if you insist...



    #1 won't work.



    #2 (given the very limited information you have supplied) might require the op-amp to dissipate as much as 600mW and stability would likely be an issue with capacitive loads. There are dedicated rail splitter chips which take stability seriously but they are not jellybean parts and, for example, the TLE2426 cannot handle the dissipation or current involved.



    I suggest something more like this (assuming you have power to spare on your 12V supply:



    enter image description here



    This uses a ubiquitous TL431 shunt regulator and boosts it with a generic PNP power transistor.



    The combination is like a precision power zener. Or just use a zener as below. Set Vo = 12V.



    Then use this circuit:





    schematic





    simulate this circuit – Schematic created using CircuitLab



    Note that if you excessively load the GND to -V the +V to GND voltage will increase to as much as 24V. Usually that's acceptable but take care about capacitor voltage rating and so on. You can add a higher voltage zener (say 14V) across R1 as a preventative measure.
    R1 will dissipate less than 1W, under normal conditions, but the zener could dissipate as much as 1.3W if 50mA flows from +V to GND and there is no corresponding current from GND to -V.



    You could use two 6.2V 1W zeners in series, for example. Keep the leads short, attach them to some PCB area and keep them apart so they run cooler.






    share|improve this answer














    You'd be better off using two 12V supplies, but if you insist...



    #1 won't work.



    #2 (given the very limited information you have supplied) might require the op-amp to dissipate as much as 600mW and stability would likely be an issue with capacitive loads. There are dedicated rail splitter chips which take stability seriously but they are not jellybean parts and, for example, the TLE2426 cannot handle the dissipation or current involved.



    I suggest something more like this (assuming you have power to spare on your 12V supply:



    enter image description here



    This uses a ubiquitous TL431 shunt regulator and boosts it with a generic PNP power transistor.



    The combination is like a precision power zener. Or just use a zener as below. Set Vo = 12V.



    Then use this circuit:





    schematic





    simulate this circuit – Schematic created using CircuitLab



    Note that if you excessively load the GND to -V the +V to GND voltage will increase to as much as 24V. Usually that's acceptable but take care about capacitor voltage rating and so on. You can add a higher voltage zener (say 14V) across R1 as a preventative measure.
    R1 will dissipate less than 1W, under normal conditions, but the zener could dissipate as much as 1.3W if 50mA flows from +V to GND and there is no corresponding current from GND to -V.



    You could use two 6.2V 1W zeners in series, for example. Keep the leads short, attach them to some PCB area and keep them apart so they run cooler.







    share|improve this answer














    share|improve this answer



    share|improve this answer








    edited yesterday

























    answered yesterday









    Spehro Pefhany

    200k4144397




    200k4144397












    • I have to keep minimal power consumption and I cant afford any change in the voltage. Thanks for the help though.
      – Ohbhatt
      yesterday






    • 1




      I wouldn't use a regulator approach to generating the virtual ground at all -- it's going to have problems either sourcing or sinking appropriate currents.
      – ThreePhaseEel
      22 hours ago


















    • I have to keep minimal power consumption and I cant afford any change in the voltage. Thanks for the help though.
      – Ohbhatt
      yesterday






    • 1




      I wouldn't use a regulator approach to generating the virtual ground at all -- it's going to have problems either sourcing or sinking appropriate currents.
      – ThreePhaseEel
      22 hours ago
















    I have to keep minimal power consumption and I cant afford any change in the voltage. Thanks for the help though.
    – Ohbhatt
    yesterday




    I have to keep minimal power consumption and I cant afford any change in the voltage. Thanks for the help though.
    – Ohbhatt
    yesterday




    1




    1




    I wouldn't use a regulator approach to generating the virtual ground at all -- it's going to have problems either sourcing or sinking appropriate currents.
    – ThreePhaseEel
    22 hours ago




    I wouldn't use a regulator approach to generating the virtual ground at all -- it's going to have problems either sourcing or sinking appropriate currents.
    – ThreePhaseEel
    22 hours ago










    up vote
    5
    down vote













    Given your desire for as low power as possible, and my realization that this common problem is seldom approached this way. I came up with a self-oscillating switching solution just for the fun of it.



    As with any switcher, single-tone emissions/ripple have to be considered (around 20kHz with these values). But if there is any significant ground current, I doubt you can be much more efficient (a more formal switcher with a separate oscillator can be made more efficient and could use a single inductor, but it would require more parts).





    schematic





    simulate this circuit – Schematic created using CircuitLab



    It is basically a relaxation oscillator that modulates the average current through L1 so that it oscillates around the required ground current. M1 and M2 are switched on and off relatively quickly (some acceleration capacitors would help with efficiency) and C12 provides positive feedback so that the opamp/comparator saturates on crossing the threshold (otherwise the load would damp the oscillator and it would become a linear regulator instead).



    L3, C10, and C11 are there to filter the ripple and to isolate the oscillation from the load, so as to avoid dampening it too much. C10, and C11 also do double-duty as the regulator input capacitance. Excess energy in L1 and L2 would be returned to the required rail and stored in them. M1 and M2 source-drain diodes are conducting in this design.



    R3,R4,R5, and R6 are chosen so as to keep M1 and M2 below threshold when there is no ground current. Unfortunately this also reduces the overall gain of the oscillator loop.



    I have not done a very careful analysis of all of the implications of this design (particularly because of it being self-oscillating), so overall stability considerations on load changes might be an issue.



    I don't think there are ICs for this type of configuration, which unnecessarily increases the part count and the design constraints. The only ones I know of are the DDR memory termination voltage regulators, but those are intended to work at very low voltages.






    share|improve this answer























    • +1, this is ingenious. But I think the reason it isn't too common is circuits which need split ground are most times for audio applications and we would certainly hear the chime.
      – Janka
      yesterday








    • 1




      Making a 400kHz-1MHz switcher is possible. You would not hear that at all!! And after all ground is the reference, it will be the rails that are moving... I am normally dealing with applications in which even 1µV of noise in high-impedance traces is an issue, we use switchers all over the place. Including driving variable analog power lines that run under those high-impedance traces. All it needs is good filtering, our only issues have arisen when the switcher control algorithms skip-beats and produce low-frequency components.
      – Edgar Brown
      yesterday










    • Yes, exactly the latter was my concern. What happens when the ground current changes direction.
      – Janka
      yesterday






    • 1




      @Janka In this architecture, assuming that it is fully stable, nothing of consequence will happen. The excess current will simply be steered via a MOSFET diode to the rail that is supplying it. Ideally zero waste power.
      – Edgar Brown
      yesterday






    • 1




      @Janka Oh, and regarding the tones, the issue only happened when during a design modification for an updated version of the product someone did not pay too much attention to a trace and made a long loop with it, which interacted with loops in the high-impedance traces. Even then the noise was barely above detection in the 2µV range. We fixed it by improving the control algorithm. In this architecture the switcher never has to go silent, small alternating pulses in both directions can ensure that. With this design that could be problematic to achieve, but a separate oscillator would fix that..
      – Edgar Brown
      yesterday















    up vote
    5
    down vote













    Given your desire for as low power as possible, and my realization that this common problem is seldom approached this way. I came up with a self-oscillating switching solution just for the fun of it.



    As with any switcher, single-tone emissions/ripple have to be considered (around 20kHz with these values). But if there is any significant ground current, I doubt you can be much more efficient (a more formal switcher with a separate oscillator can be made more efficient and could use a single inductor, but it would require more parts).





    schematic





    simulate this circuit – Schematic created using CircuitLab



    It is basically a relaxation oscillator that modulates the average current through L1 so that it oscillates around the required ground current. M1 and M2 are switched on and off relatively quickly (some acceleration capacitors would help with efficiency) and C12 provides positive feedback so that the opamp/comparator saturates on crossing the threshold (otherwise the load would damp the oscillator and it would become a linear regulator instead).



    L3, C10, and C11 are there to filter the ripple and to isolate the oscillation from the load, so as to avoid dampening it too much. C10, and C11 also do double-duty as the regulator input capacitance. Excess energy in L1 and L2 would be returned to the required rail and stored in them. M1 and M2 source-drain diodes are conducting in this design.



    R3,R4,R5, and R6 are chosen so as to keep M1 and M2 below threshold when there is no ground current. Unfortunately this also reduces the overall gain of the oscillator loop.



    I have not done a very careful analysis of all of the implications of this design (particularly because of it being self-oscillating), so overall stability considerations on load changes might be an issue.



    I don't think there are ICs for this type of configuration, which unnecessarily increases the part count and the design constraints. The only ones I know of are the DDR memory termination voltage regulators, but those are intended to work at very low voltages.






    share|improve this answer























    • +1, this is ingenious. But I think the reason it isn't too common is circuits which need split ground are most times for audio applications and we would certainly hear the chime.
      – Janka
      yesterday








    • 1




      Making a 400kHz-1MHz switcher is possible. You would not hear that at all!! And after all ground is the reference, it will be the rails that are moving... I am normally dealing with applications in which even 1µV of noise in high-impedance traces is an issue, we use switchers all over the place. Including driving variable analog power lines that run under those high-impedance traces. All it needs is good filtering, our only issues have arisen when the switcher control algorithms skip-beats and produce low-frequency components.
      – Edgar Brown
      yesterday










    • Yes, exactly the latter was my concern. What happens when the ground current changes direction.
      – Janka
      yesterday






    • 1




      @Janka In this architecture, assuming that it is fully stable, nothing of consequence will happen. The excess current will simply be steered via a MOSFET diode to the rail that is supplying it. Ideally zero waste power.
      – Edgar Brown
      yesterday






    • 1




      @Janka Oh, and regarding the tones, the issue only happened when during a design modification for an updated version of the product someone did not pay too much attention to a trace and made a long loop with it, which interacted with loops in the high-impedance traces. Even then the noise was barely above detection in the 2µV range. We fixed it by improving the control algorithm. In this architecture the switcher never has to go silent, small alternating pulses in both directions can ensure that. With this design that could be problematic to achieve, but a separate oscillator would fix that..
      – Edgar Brown
      yesterday













    up vote
    5
    down vote










    up vote
    5
    down vote









    Given your desire for as low power as possible, and my realization that this common problem is seldom approached this way. I came up with a self-oscillating switching solution just for the fun of it.



    As with any switcher, single-tone emissions/ripple have to be considered (around 20kHz with these values). But if there is any significant ground current, I doubt you can be much more efficient (a more formal switcher with a separate oscillator can be made more efficient and could use a single inductor, but it would require more parts).





    schematic





    simulate this circuit – Schematic created using CircuitLab



    It is basically a relaxation oscillator that modulates the average current through L1 so that it oscillates around the required ground current. M1 and M2 are switched on and off relatively quickly (some acceleration capacitors would help with efficiency) and C12 provides positive feedback so that the opamp/comparator saturates on crossing the threshold (otherwise the load would damp the oscillator and it would become a linear regulator instead).



    L3, C10, and C11 are there to filter the ripple and to isolate the oscillation from the load, so as to avoid dampening it too much. C10, and C11 also do double-duty as the regulator input capacitance. Excess energy in L1 and L2 would be returned to the required rail and stored in them. M1 and M2 source-drain diodes are conducting in this design.



    R3,R4,R5, and R6 are chosen so as to keep M1 and M2 below threshold when there is no ground current. Unfortunately this also reduces the overall gain of the oscillator loop.



    I have not done a very careful analysis of all of the implications of this design (particularly because of it being self-oscillating), so overall stability considerations on load changes might be an issue.



    I don't think there are ICs for this type of configuration, which unnecessarily increases the part count and the design constraints. The only ones I know of are the DDR memory termination voltage regulators, but those are intended to work at very low voltages.






    share|improve this answer














    Given your desire for as low power as possible, and my realization that this common problem is seldom approached this way. I came up with a self-oscillating switching solution just for the fun of it.



    As with any switcher, single-tone emissions/ripple have to be considered (around 20kHz with these values). But if there is any significant ground current, I doubt you can be much more efficient (a more formal switcher with a separate oscillator can be made more efficient and could use a single inductor, but it would require more parts).





    schematic





    simulate this circuit – Schematic created using CircuitLab



    It is basically a relaxation oscillator that modulates the average current through L1 so that it oscillates around the required ground current. M1 and M2 are switched on and off relatively quickly (some acceleration capacitors would help with efficiency) and C12 provides positive feedback so that the opamp/comparator saturates on crossing the threshold (otherwise the load would damp the oscillator and it would become a linear regulator instead).



    L3, C10, and C11 are there to filter the ripple and to isolate the oscillation from the load, so as to avoid dampening it too much. C10, and C11 also do double-duty as the regulator input capacitance. Excess energy in L1 and L2 would be returned to the required rail and stored in them. M1 and M2 source-drain diodes are conducting in this design.



    R3,R4,R5, and R6 are chosen so as to keep M1 and M2 below threshold when there is no ground current. Unfortunately this also reduces the overall gain of the oscillator loop.



    I have not done a very careful analysis of all of the implications of this design (particularly because of it being self-oscillating), so overall stability considerations on load changes might be an issue.



    I don't think there are ICs for this type of configuration, which unnecessarily increases the part count and the design constraints. The only ones I know of are the DDR memory termination voltage regulators, but those are intended to work at very low voltages.







    share|improve this answer














    share|improve this answer



    share|improve this answer








    edited yesterday

























    answered yesterday









    Edgar Brown

    1,68616




    1,68616












    • +1, this is ingenious. But I think the reason it isn't too common is circuits which need split ground are most times for audio applications and we would certainly hear the chime.
      – Janka
      yesterday








    • 1




      Making a 400kHz-1MHz switcher is possible. You would not hear that at all!! And after all ground is the reference, it will be the rails that are moving... I am normally dealing with applications in which even 1µV of noise in high-impedance traces is an issue, we use switchers all over the place. Including driving variable analog power lines that run under those high-impedance traces. All it needs is good filtering, our only issues have arisen when the switcher control algorithms skip-beats and produce low-frequency components.
      – Edgar Brown
      yesterday










    • Yes, exactly the latter was my concern. What happens when the ground current changes direction.
      – Janka
      yesterday






    • 1




      @Janka In this architecture, assuming that it is fully stable, nothing of consequence will happen. The excess current will simply be steered via a MOSFET diode to the rail that is supplying it. Ideally zero waste power.
      – Edgar Brown
      yesterday






    • 1




      @Janka Oh, and regarding the tones, the issue only happened when during a design modification for an updated version of the product someone did not pay too much attention to a trace and made a long loop with it, which interacted with loops in the high-impedance traces. Even then the noise was barely above detection in the 2µV range. We fixed it by improving the control algorithm. In this architecture the switcher never has to go silent, small alternating pulses in both directions can ensure that. With this design that could be problematic to achieve, but a separate oscillator would fix that..
      – Edgar Brown
      yesterday


















    • +1, this is ingenious. But I think the reason it isn't too common is circuits which need split ground are most times for audio applications and we would certainly hear the chime.
      – Janka
      yesterday








    • 1




      Making a 400kHz-1MHz switcher is possible. You would not hear that at all!! And after all ground is the reference, it will be the rails that are moving... I am normally dealing with applications in which even 1µV of noise in high-impedance traces is an issue, we use switchers all over the place. Including driving variable analog power lines that run under those high-impedance traces. All it needs is good filtering, our only issues have arisen when the switcher control algorithms skip-beats and produce low-frequency components.
      – Edgar Brown
      yesterday










    • Yes, exactly the latter was my concern. What happens when the ground current changes direction.
      – Janka
      yesterday






    • 1




      @Janka In this architecture, assuming that it is fully stable, nothing of consequence will happen. The excess current will simply be steered via a MOSFET diode to the rail that is supplying it. Ideally zero waste power.
      – Edgar Brown
      yesterday






    • 1




      @Janka Oh, and regarding the tones, the issue only happened when during a design modification for an updated version of the product someone did not pay too much attention to a trace and made a long loop with it, which interacted with loops in the high-impedance traces. Even then the noise was barely above detection in the 2µV range. We fixed it by improving the control algorithm. In this architecture the switcher never has to go silent, small alternating pulses in both directions can ensure that. With this design that could be problematic to achieve, but a separate oscillator would fix that..
      – Edgar Brown
      yesterday
















    +1, this is ingenious. But I think the reason it isn't too common is circuits which need split ground are most times for audio applications and we would certainly hear the chime.
    – Janka
    yesterday






    +1, this is ingenious. But I think the reason it isn't too common is circuits which need split ground are most times for audio applications and we would certainly hear the chime.
    – Janka
    yesterday






    1




    1




    Making a 400kHz-1MHz switcher is possible. You would not hear that at all!! And after all ground is the reference, it will be the rails that are moving... I am normally dealing with applications in which even 1µV of noise in high-impedance traces is an issue, we use switchers all over the place. Including driving variable analog power lines that run under those high-impedance traces. All it needs is good filtering, our only issues have arisen when the switcher control algorithms skip-beats and produce low-frequency components.
    – Edgar Brown
    yesterday




    Making a 400kHz-1MHz switcher is possible. You would not hear that at all!! And after all ground is the reference, it will be the rails that are moving... I am normally dealing with applications in which even 1µV of noise in high-impedance traces is an issue, we use switchers all over the place. Including driving variable analog power lines that run under those high-impedance traces. All it needs is good filtering, our only issues have arisen when the switcher control algorithms skip-beats and produce low-frequency components.
    – Edgar Brown
    yesterday












    Yes, exactly the latter was my concern. What happens when the ground current changes direction.
    – Janka
    yesterday




    Yes, exactly the latter was my concern. What happens when the ground current changes direction.
    – Janka
    yesterday




    1




    1




    @Janka In this architecture, assuming that it is fully stable, nothing of consequence will happen. The excess current will simply be steered via a MOSFET diode to the rail that is supplying it. Ideally zero waste power.
    – Edgar Brown
    yesterday




    @Janka In this architecture, assuming that it is fully stable, nothing of consequence will happen. The excess current will simply be steered via a MOSFET diode to the rail that is supplying it. Ideally zero waste power.
    – Edgar Brown
    yesterday




    1




    1




    @Janka Oh, and regarding the tones, the issue only happened when during a design modification for an updated version of the product someone did not pay too much attention to a trace and made a long loop with it, which interacted with loops in the high-impedance traces. Even then the noise was barely above detection in the 2µV range. We fixed it by improving the control algorithm. In this architecture the switcher never has to go silent, small alternating pulses in both directions can ensure that. With this design that could be problematic to achieve, but a separate oscillator would fix that..
    – Edgar Brown
    yesterday




    @Janka Oh, and regarding the tones, the issue only happened when during a design modification for an updated version of the product someone did not pay too much attention to a trace and made a long loop with it, which interacted with loops in the high-impedance traces. Even then the noise was barely above detection in the 2µV range. We fixed it by improving the control algorithm. In this architecture the switcher never has to go silent, small alternating pulses in both directions can ensure that. With this design that could be problematic to achieve, but a separate oscillator would fix that..
    – Edgar Brown
    yesterday










    up vote
    4
    down vote













    The regulators won’t work. You have zero dropout allocated to them and your ground impedance is excessive.



    The op amp is a better option, but it all depends on how much current you have going through ground. If the current is low enough you can just use a resistor divider with a couple of capacitors in parallel, if it is high you would need a hefty op amp.



    You have a couple more options:




    1. You could use two zeners with series resistors to reduce ground impedance

    2. You could put together a class AB source follower with a few resistors and two transistors (basically what the op-amp is doing but with higher impedance)

    3. If your ground current has a well-defined and consistent direction, you can use a positive or negative 12V regulator or even a transistor off one of the rails (making sure to put a bypass diode).


    But regardless of what you do, any ground current will result in wasted power (unless you figure out how to design a ground-switcher regulator of course).






    share|improve this answer





















    • Thank you for the observation.
      – Ohbhatt
      yesterday















    up vote
    4
    down vote













    The regulators won’t work. You have zero dropout allocated to them and your ground impedance is excessive.



    The op amp is a better option, but it all depends on how much current you have going through ground. If the current is low enough you can just use a resistor divider with a couple of capacitors in parallel, if it is high you would need a hefty op amp.



    You have a couple more options:




    1. You could use two zeners with series resistors to reduce ground impedance

    2. You could put together a class AB source follower with a few resistors and two transistors (basically what the op-amp is doing but with higher impedance)

    3. If your ground current has a well-defined and consistent direction, you can use a positive or negative 12V regulator or even a transistor off one of the rails (making sure to put a bypass diode).


    But regardless of what you do, any ground current will result in wasted power (unless you figure out how to design a ground-switcher regulator of course).






    share|improve this answer





















    • Thank you for the observation.
      – Ohbhatt
      yesterday













    up vote
    4
    down vote










    up vote
    4
    down vote









    The regulators won’t work. You have zero dropout allocated to them and your ground impedance is excessive.



    The op amp is a better option, but it all depends on how much current you have going through ground. If the current is low enough you can just use a resistor divider with a couple of capacitors in parallel, if it is high you would need a hefty op amp.



    You have a couple more options:




    1. You could use two zeners with series resistors to reduce ground impedance

    2. You could put together a class AB source follower with a few resistors and two transistors (basically what the op-amp is doing but with higher impedance)

    3. If your ground current has a well-defined and consistent direction, you can use a positive or negative 12V regulator or even a transistor off one of the rails (making sure to put a bypass diode).


    But regardless of what you do, any ground current will result in wasted power (unless you figure out how to design a ground-switcher regulator of course).






    share|improve this answer












    The regulators won’t work. You have zero dropout allocated to them and your ground impedance is excessive.



    The op amp is a better option, but it all depends on how much current you have going through ground. If the current is low enough you can just use a resistor divider with a couple of capacitors in parallel, if it is high you would need a hefty op amp.



    You have a couple more options:




    1. You could use two zeners with series resistors to reduce ground impedance

    2. You could put together a class AB source follower with a few resistors and two transistors (basically what the op-amp is doing but with higher impedance)

    3. If your ground current has a well-defined and consistent direction, you can use a positive or negative 12V regulator or even a transistor off one of the rails (making sure to put a bypass diode).


    But regardless of what you do, any ground current will result in wasted power (unless you figure out how to design a ground-switcher regulator of course).







    share|improve this answer












    share|improve this answer



    share|improve this answer










    answered yesterday









    Edgar Brown

    1,68616




    1,68616












    • Thank you for the observation.
      – Ohbhatt
      yesterday


















    • Thank you for the observation.
      – Ohbhatt
      yesterday
















    Thank you for the observation.
    – Ohbhatt
    yesterday




    Thank you for the observation.
    – Ohbhatt
    yesterday










    up vote
    4
    down vote













    If your 24 V is well regulated you could just use a 7812 to create a mid point and call that your 0 volt rail.





    schematic





    simulate this circuit – Schematic created using CircuitLab



    This will only work if the 24 V is independent of whatever you're powering, and as per Edgar Brown's comment, positive linear regulators like the 7812 can't sink current.






    share|improve this answer























    • That is a fantastic solution. I don't have to invest in any expensive parts. But I still have to test this circuit to verify.
      – Ohbhatt
      yesterday






    • 4




      This will only work if your ground current is positive (it exits the regulator) normal regulators don’t sink current.
      – Edgar Brown
      yesterday










    • That's a very valid point, thanks, @EdgarBrown, I've edited the answer.
      – Colin
      yesterday








    • 3




      @EdgarBrown Instead of a trusty 7812 you can use an integrated switching regulator that will generally tolerate "reverse current", they are a little more money, but same simple implementation. I have used this in a design, granted in my case most of the system was running on the 24V rail, with only a small subset of components running off the virtual ground. In any case, this becomes a matter of component selection, and 1/2/3A switching regulators can be found with bidrectional current capability, the design is solid, but the BOM may be hard to find or expensive.
      – crasic
      yesterday








    • 1




      @Ohbhatt No, that does not eliminate any change. Imagine if you connected a resistor between +12V and 0V, the regulator would not handle that because the current would be trying to go into the regulator. But a resistor between 0V and -12V would be fine. That's why it depends on your circuit design.
      – immibis
      yesterday

















    up vote
    4
    down vote













    If your 24 V is well regulated you could just use a 7812 to create a mid point and call that your 0 volt rail.





    schematic





    simulate this circuit – Schematic created using CircuitLab



    This will only work if the 24 V is independent of whatever you're powering, and as per Edgar Brown's comment, positive linear regulators like the 7812 can't sink current.






    share|improve this answer























    • That is a fantastic solution. I don't have to invest in any expensive parts. But I still have to test this circuit to verify.
      – Ohbhatt
      yesterday






    • 4




      This will only work if your ground current is positive (it exits the regulator) normal regulators don’t sink current.
      – Edgar Brown
      yesterday










    • That's a very valid point, thanks, @EdgarBrown, I've edited the answer.
      – Colin
      yesterday








    • 3




      @EdgarBrown Instead of a trusty 7812 you can use an integrated switching regulator that will generally tolerate "reverse current", they are a little more money, but same simple implementation. I have used this in a design, granted in my case most of the system was running on the 24V rail, with only a small subset of components running off the virtual ground. In any case, this becomes a matter of component selection, and 1/2/3A switching regulators can be found with bidrectional current capability, the design is solid, but the BOM may be hard to find or expensive.
      – crasic
      yesterday








    • 1




      @Ohbhatt No, that does not eliminate any change. Imagine if you connected a resistor between +12V and 0V, the regulator would not handle that because the current would be trying to go into the regulator. But a resistor between 0V and -12V would be fine. That's why it depends on your circuit design.
      – immibis
      yesterday















    up vote
    4
    down vote










    up vote
    4
    down vote









    If your 24 V is well regulated you could just use a 7812 to create a mid point and call that your 0 volt rail.





    schematic





    simulate this circuit – Schematic created using CircuitLab



    This will only work if the 24 V is independent of whatever you're powering, and as per Edgar Brown's comment, positive linear regulators like the 7812 can't sink current.






    share|improve this answer














    If your 24 V is well regulated you could just use a 7812 to create a mid point and call that your 0 volt rail.





    schematic





    simulate this circuit – Schematic created using CircuitLab



    This will only work if the 24 V is independent of whatever you're powering, and as per Edgar Brown's comment, positive linear regulators like the 7812 can't sink current.







    share|improve this answer














    share|improve this answer



    share|improve this answer








    edited yesterday

























    answered yesterday









    Colin

    2,4532920




    2,4532920












    • That is a fantastic solution. I don't have to invest in any expensive parts. But I still have to test this circuit to verify.
      – Ohbhatt
      yesterday






    • 4




      This will only work if your ground current is positive (it exits the regulator) normal regulators don’t sink current.
      – Edgar Brown
      yesterday










    • That's a very valid point, thanks, @EdgarBrown, I've edited the answer.
      – Colin
      yesterday








    • 3




      @EdgarBrown Instead of a trusty 7812 you can use an integrated switching regulator that will generally tolerate "reverse current", they are a little more money, but same simple implementation. I have used this in a design, granted in my case most of the system was running on the 24V rail, with only a small subset of components running off the virtual ground. In any case, this becomes a matter of component selection, and 1/2/3A switching regulators can be found with bidrectional current capability, the design is solid, but the BOM may be hard to find or expensive.
      – crasic
      yesterday








    • 1




      @Ohbhatt No, that does not eliminate any change. Imagine if you connected a resistor between +12V and 0V, the regulator would not handle that because the current would be trying to go into the regulator. But a resistor between 0V and -12V would be fine. That's why it depends on your circuit design.
      – immibis
      yesterday




















    • That is a fantastic solution. I don't have to invest in any expensive parts. But I still have to test this circuit to verify.
      – Ohbhatt
      yesterday






    • 4




      This will only work if your ground current is positive (it exits the regulator) normal regulators don’t sink current.
      – Edgar Brown
      yesterday










    • That's a very valid point, thanks, @EdgarBrown, I've edited the answer.
      – Colin
      yesterday








    • 3




      @EdgarBrown Instead of a trusty 7812 you can use an integrated switching regulator that will generally tolerate "reverse current", they are a little more money, but same simple implementation. I have used this in a design, granted in my case most of the system was running on the 24V rail, with only a small subset of components running off the virtual ground. In any case, this becomes a matter of component selection, and 1/2/3A switching regulators can be found with bidrectional current capability, the design is solid, but the BOM may be hard to find or expensive.
      – crasic
      yesterday








    • 1




      @Ohbhatt No, that does not eliminate any change. Imagine if you connected a resistor between +12V and 0V, the regulator would not handle that because the current would be trying to go into the regulator. But a resistor between 0V and -12V would be fine. That's why it depends on your circuit design.
      – immibis
      yesterday


















    That is a fantastic solution. I don't have to invest in any expensive parts. But I still have to test this circuit to verify.
    – Ohbhatt
    yesterday




    That is a fantastic solution. I don't have to invest in any expensive parts. But I still have to test this circuit to verify.
    – Ohbhatt
    yesterday




    4




    4




    This will only work if your ground current is positive (it exits the regulator) normal regulators don’t sink current.
    – Edgar Brown
    yesterday




    This will only work if your ground current is positive (it exits the regulator) normal regulators don’t sink current.
    – Edgar Brown
    yesterday












    That's a very valid point, thanks, @EdgarBrown, I've edited the answer.
    – Colin
    yesterday






    That's a very valid point, thanks, @EdgarBrown, I've edited the answer.
    – Colin
    yesterday






    3




    3




    @EdgarBrown Instead of a trusty 7812 you can use an integrated switching regulator that will generally tolerate "reverse current", they are a little more money, but same simple implementation. I have used this in a design, granted in my case most of the system was running on the 24V rail, with only a small subset of components running off the virtual ground. In any case, this becomes a matter of component selection, and 1/2/3A switching regulators can be found with bidrectional current capability, the design is solid, but the BOM may be hard to find or expensive.
    – crasic
    yesterday






    @EdgarBrown Instead of a trusty 7812 you can use an integrated switching regulator that will generally tolerate "reverse current", they are a little more money, but same simple implementation. I have used this in a design, granted in my case most of the system was running on the 24V rail, with only a small subset of components running off the virtual ground. In any case, this becomes a matter of component selection, and 1/2/3A switching regulators can be found with bidrectional current capability, the design is solid, but the BOM may be hard to find or expensive.
    – crasic
    yesterday






    1




    1




    @Ohbhatt No, that does not eliminate any change. Imagine if you connected a resistor between +12V and 0V, the regulator would not handle that because the current would be trying to go into the regulator. But a resistor between 0V and -12V would be fine. That's why it depends on your circuit design.
    – immibis
    yesterday






    @Ohbhatt No, that does not eliminate any change. Imagine if you connected a resistor between +12V and 0V, the regulator would not handle that because the current would be trying to go into the regulator. But a resistor between 0V and -12V would be fine. That's why it depends on your circuit design.
    – immibis
    yesterday












    up vote
    2
    down vote













    I think NJM4556A would work



    you can draw current from negative and positive rails but there difference not to exceed the OP amp output current.



    Note: I'm not experienced, i suggest you to read the following post



    EEVBLOG - my-negative-voltage-rail-doesnt-work






    share|improve this answer





















    • That is a good idea. I will took into that.
      – Ohbhatt
      yesterday















    up vote
    2
    down vote













    I think NJM4556A would work



    you can draw current from negative and positive rails but there difference not to exceed the OP amp output current.



    Note: I'm not experienced, i suggest you to read the following post



    EEVBLOG - my-negative-voltage-rail-doesnt-work






    share|improve this answer





















    • That is a good idea. I will took into that.
      – Ohbhatt
      yesterday













    up vote
    2
    down vote










    up vote
    2
    down vote









    I think NJM4556A would work



    you can draw current from negative and positive rails but there difference not to exceed the OP amp output current.



    Note: I'm not experienced, i suggest you to read the following post



    EEVBLOG - my-negative-voltage-rail-doesnt-work






    share|improve this answer












    I think NJM4556A would work



    you can draw current from negative and positive rails but there difference not to exceed the OP amp output current.



    Note: I'm not experienced, i suggest you to read the following post



    EEVBLOG - my-negative-voltage-rail-doesnt-work







    share|improve this answer












    share|improve this answer



    share|improve this answer










    answered yesterday









    Hasan alattar

    596




    596












    • That is a good idea. I will took into that.
      – Ohbhatt
      yesterday


















    • That is a good idea. I will took into that.
      – Ohbhatt
      yesterday
















    That is a good idea. I will took into that.
    – Ohbhatt
    yesterday




    That is a good idea. I will took into that.
    – Ohbhatt
    yesterday










    up vote
    0
    down vote













    There are many low-cost methods. But switching method may help you with a minimum component that available everywhere.



    you can use a flyback converter with a minimum circuit:



    Edited: The main circuit:
    mix circuit
    Ref: a mix of two links (http://uzzors2k.4hv.org/index.phppage=flybacktransformerdrivers, https://wiki.analog.com/university/courses/electronics/text/chapter-6)



    Component list:




    • Zener diode


    • 555 IC


    • Mosfet


    • A toroid, the transformer can be made with wire and a toroid core


    • Diode in output


    • some capacitor


    • some resistor


    • some wire



    Benefits:




    • you can generate any voltage in output even bigger than your first voltage


    • these components are available everywhere


    • you can generate any voltage even isolated voltage


    • you can increase your power by changing the Mosfet and selecting a bigger toroid.



    The main references:



    http://uzzors2k.4hv.org/index.php?page=flybacktransformerdrivers
    enter image description here



    Additionally, you need a Zener diode for 12-15volt and a 555 IC.( your coil feed with 24Volt but for 555, you should generate a 12-volt power with a Zener diode).



    in the output, you need a diode with a capacitor.
    link: https://wiki.analog.com/university/courses/electronics/text/chapter-6
    enter image description here



    It is dual polarity Full-wave rectifier using a center tapped transformer and 4 diodes






    share|improve this answer



























      up vote
      0
      down vote













      There are many low-cost methods. But switching method may help you with a minimum component that available everywhere.



      you can use a flyback converter with a minimum circuit:



      Edited: The main circuit:
      mix circuit
      Ref: a mix of two links (http://uzzors2k.4hv.org/index.phppage=flybacktransformerdrivers, https://wiki.analog.com/university/courses/electronics/text/chapter-6)



      Component list:




      • Zener diode


      • 555 IC


      • Mosfet


      • A toroid, the transformer can be made with wire and a toroid core


      • Diode in output


      • some capacitor


      • some resistor


      • some wire



      Benefits:




      • you can generate any voltage in output even bigger than your first voltage


      • these components are available everywhere


      • you can generate any voltage even isolated voltage


      • you can increase your power by changing the Mosfet and selecting a bigger toroid.



      The main references:



      http://uzzors2k.4hv.org/index.php?page=flybacktransformerdrivers
      enter image description here



      Additionally, you need a Zener diode for 12-15volt and a 555 IC.( your coil feed with 24Volt but for 555, you should generate a 12-volt power with a Zener diode).



      in the output, you need a diode with a capacitor.
      link: https://wiki.analog.com/university/courses/electronics/text/chapter-6
      enter image description here



      It is dual polarity Full-wave rectifier using a center tapped transformer and 4 diodes






      share|improve this answer

























        up vote
        0
        down vote










        up vote
        0
        down vote









        There are many low-cost methods. But switching method may help you with a minimum component that available everywhere.



        you can use a flyback converter with a minimum circuit:



        Edited: The main circuit:
        mix circuit
        Ref: a mix of two links (http://uzzors2k.4hv.org/index.phppage=flybacktransformerdrivers, https://wiki.analog.com/university/courses/electronics/text/chapter-6)



        Component list:




        • Zener diode


        • 555 IC


        • Mosfet


        • A toroid, the transformer can be made with wire and a toroid core


        • Diode in output


        • some capacitor


        • some resistor


        • some wire



        Benefits:




        • you can generate any voltage in output even bigger than your first voltage


        • these components are available everywhere


        • you can generate any voltage even isolated voltage


        • you can increase your power by changing the Mosfet and selecting a bigger toroid.



        The main references:



        http://uzzors2k.4hv.org/index.php?page=flybacktransformerdrivers
        enter image description here



        Additionally, you need a Zener diode for 12-15volt and a 555 IC.( your coil feed with 24Volt but for 555, you should generate a 12-volt power with a Zener diode).



        in the output, you need a diode with a capacitor.
        link: https://wiki.analog.com/university/courses/electronics/text/chapter-6
        enter image description here



        It is dual polarity Full-wave rectifier using a center tapped transformer and 4 diodes






        share|improve this answer














        There are many low-cost methods. But switching method may help you with a minimum component that available everywhere.



        you can use a flyback converter with a minimum circuit:



        Edited: The main circuit:
        mix circuit
        Ref: a mix of two links (http://uzzors2k.4hv.org/index.phppage=flybacktransformerdrivers, https://wiki.analog.com/university/courses/electronics/text/chapter-6)



        Component list:




        • Zener diode


        • 555 IC


        • Mosfet


        • A toroid, the transformer can be made with wire and a toroid core


        • Diode in output


        • some capacitor


        • some resistor


        • some wire



        Benefits:




        • you can generate any voltage in output even bigger than your first voltage


        • these components are available everywhere


        • you can generate any voltage even isolated voltage


        • you can increase your power by changing the Mosfet and selecting a bigger toroid.



        The main references:



        http://uzzors2k.4hv.org/index.php?page=flybacktransformerdrivers
        enter image description here



        Additionally, you need a Zener diode for 12-15volt and a 555 IC.( your coil feed with 24Volt but for 555, you should generate a 12-volt power with a Zener diode).



        in the output, you need a diode with a capacitor.
        link: https://wiki.analog.com/university/courses/electronics/text/chapter-6
        enter image description here



        It is dual polarity Full-wave rectifier using a center tapped transformer and 4 diodes







        share|improve this answer














        share|improve this answer



        share|improve this answer








        edited yesterday

























        answered yesterday









        M KS

        868




        868






























             

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