Inverting vs NonInverting Mosfet Driver

I have some fuzzy recollection of reading to the effect that
noninverting mosfet drivers are more prone to instability due to layout
effects.

Confirm?

Just doing a quick sim in my head:
With poor layout, when a noninverting mosfet driver turns on (sourcing),
the signal ground pops up due to the mosfet gate capacitance (iirc
called ground bounce?) then the driver sees a valid (actually invalid)
'0' threshold to turn the mosfet drive off.. The driver oscillates.

Is it best to use a noninverting mosfet driver in a smps design?

I have some fuzzy recollection of reading to the effect that
noninverting mosfet drivers are more prone to instability due to layout
effects.

Confirm?

Just doing a quick sim in my head:
With poor layout, when a noninverting mosfet driver turns on (sourcing),
the signal ground pops up due to the mosfet gate capacitance (iirc
called ground bounce?) then the driver sees a valid (actually invalid)
'0' threshold to turn the mosfet drive off.. The driver oscillates.

Is it best to use a noninverting mosfet driver in a smps design?

I have some fuzzy recollection of reading to the effect that
noninverting mosfet drivers are more prone to instability due to layout
effects.

Confirm?

Just doing a quick sim in my head:
With poor layout, when a noninverting mosfet driver turns on (sourcing),
the signal ground pops up due to the mosfet gate capacitance (iirc
called ground bounce?) then the driver sees a valid (actually invalid)
'0' threshold to turn the mosfet drive off.. The driver oscillates.

Is it best to use a noninverting mosfet driver in a smps design?

On Mon, 8 Feb 2010 13:01:17 -0800, D from BC <myrealaddress_at_comic.com
wrote:

I have some fuzzy recollection of reading to the effect that
noninverting mosfet drivers are more prone to instability due to layout
effects.

Confirm?

Just doing a quick sim in my head:
With poor layout, when a noninverting mosfet driver turns on (sourcing),
the signal ground pops up due to the mosfet gate capacitance (iirc
called ground bounce?) then the driver sees a valid (actually invalid)
'0' threshold to turn the mosfet drive off.. The driver oscillates.

Is it best to use a noninverting mosfet driver in a smps design?

You have to test drive any prospective part, by any mfr, in-circuit.
Duals and non-inverters are more prone to misbehaviour. Low voltage

logic level inputs are a mistake to be avoided, wherever possible,
even with a 'ground plane'. Some parts are even sensitive to output
disturbances, never mind ground bounce on the input, regardless of
sales blurbs or specsmanship.

For non-inversion, bypass Micrel MIC4424 parts, if you want to avoid
grey hair. Similar lower-powered Maxim parts MAX4427A or Micrel TC4427
seemed OK, although I recall a lack of internal UVLO, which required
vigilance.

RL

On Mon, 8 Feb 2010 13:01:17 -0800, D from BC <myrealaddress_at_comic.com
wrote:

I have some fuzzy recollection of reading to the effect that
noninverting mosfet drivers are more prone to instability due to layout
effects.

Confirm?

Just doing a quick sim in my head:
With poor layout, when a noninverting mosfet driver turns on (sourcing),
the signal ground pops up due to the mosfet gate capacitance (iirc
called ground bounce?) then the driver sees a valid (actually invalid)
'0' threshold to turn the mosfet drive off.. The driver oscillates.

Is it best to use a noninverting mosfet driver in a smps design?

You have to test drive any prospective part, by any mfr, in-circuit.
Duals and non-inverters are more prone to misbehaviour. Low voltage
logic level inputs are a mistake to be avoided, wherever possible,
even with a 'ground plane'. Some parts are even sensitive to output
disturbances, never mind ground bounce on the input, regardless of
sales blurbs or specsmanship.

For non-inversion, bypass Micrel MIC4424 parts, if you want to avoid
grey hair. Similar lower-powered Maxim parts MAX4427A or Micrel TC4427
seemed OK, although I recall a lack of internal UVLO, which required
vigilance.

legg wrote:
On Mon, 8 Feb 2010 13:01:17 -0800, D from BC <myrealaddress_at_comic.com
wrote:

I have some fuzzy recollection of reading to the effect that
noninverting mosfet drivers are more prone to instability due to layout
effects.

Confirm?

Just doing a quick sim in my head:
With poor layout, when a noninverting mosfet driver turns on (sourcing),
the signal ground pops up due to the mosfet gate capacitance (iirc
called ground bounce?) then the driver sees a valid (actually invalid)
'0' threshold to turn the mosfet drive off.. The driver oscillates.

Is it best to use a noninverting mosfet driver in a smps design?

You have to test drive any prospective part, by any mfr, in-circuit.
Duals and non-inverters are more prone to misbehaviour. Low voltage
logic level inputs are a mistake to be avoided, wherever possible,
even with a 'ground plane'. Some parts are even sensitive to output
disturbances, never mind ground bounce on the input, regardless of
sales blurbs or specsmanship.

For non-inversion, bypass Micrel MIC4424 parts, if you want to avoid
grey hair. Similar lower-powered Maxim parts MAX4427A or Micrel TC4427
seemed OK, although I recall a lack of internal UVLO, which required
vigilance.


Never had a problem with Micrel MOSFET drivers. What caused the gray hair?

On Tue, 09 Feb 2010 14:34:33 -0800, Joerg <invalid_at_invalid.invalid
wrote:

legg wrote:
On Mon, 8 Feb 2010 13:01:17 -0800, D from BC <myrealaddress_at_comic.com
wrote:

I have some fuzzy recollection of reading to the effect that
noninverting mosfet drivers are more prone to instability due to layout
effects.

Confirm?

Just doing a quick sim in my head:
With poor layout, when a noninverting mosfet driver turns on (sourcing),
the signal ground pops up due to the mosfet gate capacitance (iirc
called ground bounce?) then the driver sees a valid (actually invalid)
'0' threshold to turn the mosfet drive off.. The driver oscillates.

Is it best to use a noninverting mosfet driver in a smps design?
You have to test drive any prospective part, by any mfr, in-circuit.
Duals and non-inverters are more prone to misbehaviour. Low voltage
logic level inputs are a mistake to be avoided, wherever possible,
even with a 'ground plane'. Some parts are even sensitive to output
disturbances, never mind ground bounce on the input, regardless of
sales blurbs or specsmanship.

For non-inversion, bypass Micrel MIC4424 parts, if you want to avoid
grey hair. Similar lower-powered Maxim parts MAX4427A or Micrel TC4427
seemed OK, although I recall a lack of internal UVLO, which required
vigilance.

Never had a problem with Micrel MOSFET drivers. What caused the gray hair?

Basically, I had opposing mosfet outputs turning on by themselves on
the low side of a full bridge driver. The duration of conduction could
be reduced but not eliminated with agressive supply decoupling. The
input of the offender scoped slightly negative during the entire drive
fault period, following a positive glitche of 100nS duration,
possibly generated by it's partner. No other pin-compatible part
behaved this way, in the same physical position.

In it's 'representative schematic', the 4424 input is depicted as
analog, with some kind of current hysterisis introduced to the signal,
at the receiver's output, which is just plain barmy, IMHO.

legg wrote:
On Mon, 8 Feb 2010 13:01:17 -0800, D from BC <myrealaddr...@comic.com
wrote:

I have some fuzzy recollection of reading to the effect that
noninverting mosfet drivers are more prone to instability due to layout
effects.

Confirm?

Just doing a quick sim in my head:
With poor layout, when a noninverting mosfet driver turns on (sourcing),
the signal ground pops up due to the mosfet gate capacitance (iirc
called ground bounce?) then the driver sees a valid (actually invalid)
'0' threshold to turn the mosfet drive off.. The driver oscillates.

Is it best to use a noninverting mosfet driver in a smps design?

You have to test drive any prospective part, by any mfr, in-circuit.
Duals and non-inverters are more prone to misbehaviour. Low voltage
logic level inputs are a mistake to be avoided, wherever possible,
even with a 'ground plane'. Some parts are even sensitive to output
disturbances, never mind ground bounce on the input, regardless of
sales blurbs or specsmanship.

For non-inversion, bypass Micrel MIC4424 parts, if you want to avoid
grey hair. Similar lower-powered Maxim parts MAX4427A or Micrel TC4427
seemed OK, although I recall a lack of internal UVLO, which required
vigilance.

Never had a problem with Micrel MOSFET drivers. What caused the gray hair?

--
Regards, Joerg

http://www.analogconsultants.com/

"gmail" domain blocked because of excessive spam.
Use another domain or send PM.

You have to test drive any prospective part, by any mfr, in-circuit.
Duals and non-inverters are more prone to misbehaviour. Low voltage
logic level inputs are a mistake to be avoided, wherever possible,
even with a 'ground plane'. Some parts are even sensitive to output
disturbances, never mind ground bounce on the input, regardless of
sales blurbs or specsmanship.

For non-inversion, bypass Micrel MIC4424 parts, if you want to avoid
grey hair. Similar lower-powered Maxim parts MAX4427A or Micrel TC4427
seemed OK, although I recall a lack of internal UVLO, which required
vigilance.

Never had a problem with Micrel MOSFET drivers. What caused the gray hair?

Basically, I had opposing mosfet outputs turning on by themselves on
the low side of a full bridge driver. The duration of conduction could
be reduced but not eliminated with agressive supply decoupling. The
input of the offender scoped slightly negative during the entire drive
fault period, following a positive glitche of 100nS duration,
possibly generated by it's partner. No other pin-compatible part
behaved this way, in the same physical position.


That almost sounds like a damaged chip. I've mainly used the 4421 but
AFAIK they are all the same architecture. Ok, they aren't really
shoot-through protected but they ran nice and cool at a few hundred kHz.
They do need a really stiff supply with two planes and good X7R caps,
else all hell can break loose. It also does if you hang too big a gate
capacitance onto it, which I guess is why they also make 6A, 9A and 12A
devices.

This was not a damaged chip - substitutions and iterations in

In it's 'representative schematic', the 4424 input is depicted as
analog, with some kind of current hysterisis introduced to the signal,
at the receiver's output, which is just plain barmy, IMHO.


It actually works, a few hundred mV hysteresis. Not barmy

On Tue, 09 Feb 2010 18:18:54 -0800, Joerg <invalid_at_invalid.invalid
wrote:

snip
You have to test drive any prospective part, by any mfr, in-circuit.
Duals and non-inverters are more prone to misbehaviour. Low voltage
logic level inputs are a mistake to be avoided, wherever possible,
even with a 'ground plane'. Some parts are even sensitive to output
disturbances, never mind ground bounce on the input, regardless of
sales blurbs or specsmanship.

For non-inversion, bypass Micrel MIC4424 parts, if you want to avoid
grey hair. Similar lower-powered Maxim parts MAX4427A or Micrel TC4427
seemed OK, although I recall a lack of internal UVLO, which required
vigilance.

Never had a problem with Micrel MOSFET drivers. What caused the gray hair?
Basically, I had opposing mosfet outputs turning on by themselves on
the low side of a full bridge driver. The duration of conduction could
be reduced but not eliminated with agressive supply decoupling. The
input of the offender scoped slightly negative during the entire drive
fault period, following a positive glitche of 100nS duration,
possibly generated by it's partner. No other pin-compatible part
behaved this way, in the same physical position.

That almost sounds like a damaged chip. I've mainly used the 4421 but
AFAIK they are all the same architecture. Ok, they aren't really
shoot-through protected but they ran nice and cool at a few hundred kHz.
They do need a really stiff supply with two planes and good X7R caps,
else all hell can break loose. It also does if you hang too big a gate
capacitance onto it, which I guess is why they also make 6A, 9A and 12A
devices.

This was not a damaged chip - substitutions and iterations in
documentatiomn of the fault established this. All outputs were only
required to drive the gate limiting resistor, which dominated gate
current control in an assisted switching circuit, where the big fet in
question had it's active capacitances discharged in advance by an
external switch.

I suspect it might have been the reverse transfer current hitting the
output, before it was required to be active high, that scrambled
adjacent internal logic of it's partner, somehow, but that is just
speculation. I wasn't prepared to rip apart the entire topology in
order to investigate further, with functional substitutes on-hand.

In it's 'representative schematic', the 4424 input is depicted as
analog, with some kind of current hysterisis introduced to the signal,
at the receiver's output, which is just plain barmy, IMHO.

It actually works, a few hundred mV hysteresis. Not barmy :-)

It obviously doesn't work well enough to be specified in the part's
datasheet, as such. The concept should have been buried on that basis
alone.