Parasitic capacitance of SMD resistors and their generated noise

Post by ***@gmail.com
Hello, colleagues
My question is about basic component that we all
are working with - resistor, actually SMD 0402 type of them. There
are few technologies on the market to make them - thick film, thin
film, metal film, and probably some more. Resistors produced by
different technologies has different performance. Currently I am
interested in three characteristics for 0402 size of resistors -
parasitic parallel capacitance, parasitic series inductance, and
generated noise, and their repeatability/stability/predictability in
production. I am talking about frequency range from DC and up to 2
GHz. Could you provide/reveal values of these properties of 0402
resistors made by each of above technologies? Any additional
information will be appreciated. Thank you

I measured parasitic capacitance and inductance for 1206 resistors
and got about 50fF and 500pH. I'd expect about the same for 0402,
because they have the same shape. Of course, pad layout and trace
width matters, as does the proximity of other conductors. I only
measured 1% metal film resistors.

Common wisdom says that only metal film should be used where noise
matters. I never made comparative measurements. In my field,
resistor cost is relatively negligible, so I tend to use metal
film almost everywhere.

Jeroen Belleman

j***@highlandsniptechnology.com

2022-03-07 15:31:26 UTC

On Mon, 07 Mar 2022 12:50:45 +0100, Jeroen Belleman

The parasitics of various resistors are easily googled.

Post by Jeroen Belleman
Common wisdom says that only metal film should be used where noise
matters. I never made comparative measurements. In my field,
resistor cost is relatively negligible, so I tend to use metal
film almost everywhere.
Jeroen Belleman

Johnson noise must be the same regardless of the materials.

Thick-film resistors can have excess noise if there is voltage across
them, but it's hard to measure. I managed to measure some once, but it
took very high value resistors and high voltages.

High tempco resistors in a voltage divider or equivalent can make low
frequency (subsonic) noise from small temperature fluctuations.

--
I yam what I yam - Popeye

Phil Hobbs

2022-03-07 17:03:17 UTC

Post by j***@highlandsniptechnology.com
On Mon, 07 Mar 2022 12:50:45 +0100, Jeroen Belleman

The parasitics of various resistors are easily googled.

As Kipling's Shipwrecked Mariner said to the Whale, "Not so, but far
otherwise." (At least in my business, i.e. ultrasensitive measurements,
that is.)

One time I was chasing my tail for about a day, trying to figure out why
my shiny new super low noise laser driver gizmo was exhibiting horrific
1/f noise on the spectrum analyzer. It turned out to be the classic
Tektronix 50-ohm 2-W BNC feedthrough terminator I was using--it was made
of cermet. Switching to metal film dropped the 1/f noise by about two
orders of magnitude IIRC. Not subtle at all.

Post by j***@highlandsniptechnology.com
High tempco resistors in a voltage divider or equivalent can make low
frequency (subsonic) noise from small temperature fluctuations.

Yup. Random temperature drift has roughly a 1/f**2 noise PSD.

The LIGO folks published a study on noise in resistors, IIRC, but I'm
not laying my hands on it at the moment.

Cheers

Phil Hobbs

--
Dr Philip C D Hobbs
Principal Consultant
ElectroOptical Innovations LLC / Hobbs ElectroOptics
Optics, Electro-optics, Photonics, Analog Electronics
Briarcliff Manor NY 10510

http://electrooptical.net
http://hobbs-eo.com

j***@highlandsniptechnology.com

2022-03-07 17:19:21 UTC

On Mon, 7 Mar 2022 12:03:17 -0500, Phil Hobbs

Post by j***@highlandsniptechnology.com
On Mon, 07 Mar 2022 12:50:45 +0100, Jeroen Belleman

The parasitics of various resistors are easily googled.

As Kipling's Shipwrecked Mariner said to the Whale, "Not so, but far
otherwise." (At least in my business, i.e. ultrasensitive measurements,
that is.)
One time I was chasing my tail for about a day, trying to figure out why
my shiny new super low noise laser driver gizmo was exhibiting horrific
1/f noise on the spectrum analyzer. It turned out to be the classic
Tektronix 50-ohm 2-W BNC feedthrough terminator I was using--it was made
of cermet. Switching to metal film dropped the 1/f noise by about two
orders of magnitude IIRC. Not subtle at all.

Was there voltage across that terminator? Was it making unusually
large amounts of Johnson noise?

--
I yam what I yam - Popeye

Phil Hobbs

2022-03-07 17:35:32 UTC

Post by j***@highlandsniptechnology.com
On Mon, 7 Mar 2022 12:03:17 -0500, Phil Hobbs

Post by j***@highlandsniptechnology.com
On Mon, 07 Mar 2022 12:50:45 +0100, Jeroen Belleman

The parasitics of various resistors are easily googled.

As Kipling's Shipwrecked Mariner said to the Whale, "Not so, but far
otherwise." (At least in my business, i.e. ultrasensitive measurements,
that is.)
One time I was chasing my tail for about a day, trying to figure out why
my shiny new super low noise laser driver gizmo was exhibiting horrific
1/f noise on the spectrum analyzer. It turned out to be the classic
Tektronix 50-ohm 2-W BNC feedthrough terminator I was using--it was made
of cermet. Switching to metal film dropped the 1/f noise by about two
orders of magnitude IIRC. Not subtle at all.

Was there voltage across that terminator? Was it making unusually
large amounts of Johnson noise?

Yes, I was pumping a couple of hundred milliamps into it. 1/f noise
arises from conductance fluctuations, so it doesn't appear unless
there's current flowing. As you say, Johnson noise depends only on the
resistance and the temperature, but of course it also assumes thermal
equilibrium, which stops applying when the power gets turned on.

Cheers

John Larkin

2022-03-07 18:16:11 UTC

On Mon, 7 Mar 2022 12:35:32 -0500, Phil Hobbs

Post by j***@highlandsniptechnology.com
On Mon, 7 Mar 2022 12:03:17 -0500, Phil Hobbs

Post by j***@highlandsniptechnology.com
On Mon, 07 Mar 2022 12:50:45 +0100, Jeroen Belleman

The parasitics of various resistors are easily googled.

As Kipling's Shipwrecked Mariner said to the Whale, "Not so, but far
otherwise." (At least in my business, i.e. ultrasensitive measurements,
that is.)
One time I was chasing my tail for about a day, trying to figure out why
my shiny new super low noise laser driver gizmo was exhibiting horrific
1/f noise on the spectrum analyzer. It turned out to be the classic
Tektronix 50-ohm 2-W BNC feedthrough terminator I was using--it was made
of cermet. Switching to metal film dropped the 1/f noise by about two
orders of magnitude IIRC. Not subtle at all.

Was there voltage across that terminator? Was it making unusually
large amounts of Johnson noise?

It's probably too late, but it would be interesting to measure the 1/f
noise vs current. It might be square law, namely thermal.

Thinfilms have much lower tempcos than cermets. There could be
micro/localized thermal effects too, like at grain boundaries. Laser
trimming can create horrors.

I found it difficult to measure excess noise in cermets, and it was in
the ballpark of the Johnson noise. These were megohm range values, so
self-heating was negligable.

Then it was hard to find 10M sorts of thinfilms.

--
If a man will begin with certainties, he shall end with doubts,
but if he will be content to begin with doubts he shall end in certainties.
Francis Bacon

Phil Hobbs

2022-03-07 19:47:04 UTC

Post by John Larkin
On Mon, 7 Mar 2022 12:35:32 -0500, Phil Hobbs

Post by j***@highlandsniptechnology.com
On Mon, 7 Mar 2022 12:03:17 -0500, Phil Hobbs

Post by j***@highlandsniptechnology.com
On Mon, 07 Mar 2022 12:50:45 +0100, Jeroen Belleman

The parasitics of various resistors are easily googled.

As Kipling's Shipwrecked Mariner said to the Whale, "Not so, but far
otherwise." (At least in my business, i.e. ultrasensitive measurements,
that is.)
One time I was chasing my tail for about a day, trying to figure out why
my shiny new super low noise laser driver gizmo was exhibiting horrific
1/f noise on the spectrum analyzer. It turned out to be the classic
Tektronix 50-ohm 2-W BNC feedthrough terminator I was using--it was made
of cermet. Switching to metal film dropped the 1/f noise by about two
orders of magnitude IIRC. Not subtle at all.

Was there voltage across that terminator? Was it making unusually
large amounts of Johnson noise?

It's probably too late, but it would be interesting to measure the 1/f
noise vs current. It might be square law, namely thermal.

Nah, definitely linear, and definitely 1/f not 1/f**2. A constant-rate
drift notionally has a spectrum that goes as 1/f**4, and a random-walk
drift ('brown noise') goes as 1/f**2. That's what you usually see go
away when you put styrofoam on top of the resistor.

It's quite possible that the conductivity fluctuations depend on
temperature, but I don't recall hearing that mentioned.

Post by John Larkin
Thinfilms have much lower tempcos than cermets. There could be
micro/localized thermal effects too, like at grain boundaries. Laser
trimming can create horrors.
I found it difficult to measure excess noise in cermets, and it was in
the ballpark of the Johnson noise. These were megohm range values, so
self-heating was negligable.
Then it was hard to find 10M sorts of thinfilms.

Well, believe me, this example was the very furthest thing from subtle.

Cheers

Phil Hobbs

whit3rd

2022-03-07 21:09:19 UTC

Post by John Larkin
On Mon, 7 Mar 2022 12:35:32 -0500, Phil Hobbs

Post by j***@highlandsniptechnology.com
On Mon, 7 Mar 2022 12:03:17 -0500, Phil Hobbs

...gizmo was exhibiting horrific
1/f noise on the spectrum analyzer. It turned out to be the classic
Tektronix 50-ohm 2-W BNC feedthrough terminator I was using--it was made
of cermet. Switching to metal film dropped the 1/f noise by about two
orders of magnitude IIRC. Not subtle at all.

It's probably too late, but it would be interesting to measure the 1/f
noise vs current. It might be square law, namely thermal.

Nah, definitely linear, and definitely 1/f not 1/f**2. A constant-rate
drift notionally has a spectrum that goes as 1/f**4, and a random-walk
drift ('brown noise') goes as 1/f**2.

Carbon resistors are semi-metals, so they get recombination noise; probably
the 'cermet' is a similar material. For metal film, though, it's terribly difficult to
get a thin and long continuous metal path for high resistance, AND keep it from
oxidizing and changing value. So, carbon (carbon film?) still is the solution for high-ohms
items.

John Larkin

2022-03-07 21:26:28 UTC

Post by whit3rd

Post by John Larkin
On Mon, 7 Mar 2022 12:35:32 -0500, Phil Hobbs

Post by j***@highlandsniptechnology.com
On Mon, 7 Mar 2022 12:03:17 -0500, Phil Hobbs

It's probably too late, but it would be interesting to measure the 1/f
noise vs current. It might be square law, namely thermal.

Nah, definitely linear, and definitely 1/f not 1/f**2. A constant-rate
drift notionally has a spectrum that goes as 1/f**4, and a random-walk
drift ('brown noise') goes as 1/f**2.

I have some 1T ohm surface-mount cermet resistors.

--
If a man will begin with certainties, he shall end with doubts,
but if he will be content to begin with doubts he shall end in certainties.
Francis Bacon

Phil Hobbs

2022-03-07 21:27:20 UTC

Post by whit3rd

Post by John Larkin
On Mon, 7 Mar 2022 12:35:32 -0500, Phil Hobbs

Post by j***@highlandsniptechnology.com
On Mon, 7 Mar 2022 12:03:17 -0500, Phil Hobbs

...gizmo was exhibiting horrific 1/f noise on the spectrum
analyzer. It turned out to be the classic Tektronix 50-ohm
2-W BNC feedthrough terminator I was using--it was made of
cermet. Switching to metal film dropped the 1/f noise by
about two orders of magnitude IIRC. Not subtle at all.

It's probably too late, but it would be interesting to measure
the 1/f noise vs current. It might be square law, namely
thermal.

Nah, definitely linear, and definitely 1/f not 1/f**2. A
constant-rate drift notionally has a spectrum that goes as 1/f**4,
and a random-walk drift ('brown noise') goes as 1/f**2.

Carbon resistors are semi-metals, so they get recombination noise;

Not sure what you mean by that, exactly. To get recombination noise you
need minority carriers, no?

Post by whit3rd
probably the 'cermet' is a similar material.

Cermets aren't homogeneous--as the name implies, they're ceramic/metal
composites.

Post by whit3rd
For metal film, though, it's terribly difficult to get a thin and
long continuous metal path for high resistance,

Why so? I used to make conducting films of 100 angstroms or so. Atoms
are pretty small, and using sputtering as opposed to directional
evaporation will make the film follow even rough substrates pretty well.

Post by whit3rd
AND keep it from oxidizing and changing value. > So, carbon (carbon
film?) still is the solution for high-ohms items.

It's certainly true that it's harder to make very high resistances out
of very low resistance materials, and there are lots of low-precision
applications where 1/f noise is not a serious issue--overvoltage
protection, for instance.

However, carbon resistors are seriously nonlinear at high voltages--the
resistance of old style Allen-Bradley carbon comps was allowed to drop
by a quarter at their upper voltage limit.

Cheers

Phil Hobbs

Phil Allison

2022-03-07 22:06:21 UTC

Phil Hobbs wrote:
==============

Post by Phil Hobbs
However, carbon resistors are seriously nonlinear at high voltages--the
resistance of old style Allen-Bradley carbon comps was allowed to drop
by a quarter at their upper voltage limit.

** Really ????
That is massively ambiguous.

CC resistors can drop in value if they run hot and over time.
Mostly they slowly drift high, over a period of decades.

Crazy to crazy that " non linearity".

..... Phil

John Larkin

2022-03-07 22:52:10 UTC

On Mon, 7 Mar 2022 14:06:21 -0800 (PST), Phil Allison

Post by Phil Allison
==============

** Really ????
That is massively ambiguous.
CC resistors can drop in value if they run hot and over time.
Mostly they slowly drift high, over a period of decades.
Crazy to crazy that " non linearity".
..... Phil

google resistor voltage coefficient

Carbons can be ballpark 100 PPM/volt.

--
If a man will begin with certainties, he shall end with doubts,
but if he will be content to begin with doubts he shall end in certainties.
Francis Bacon

Phil Allison

2022-03-07 23:07:49 UTC

John Larkin bullshitted as usual wrote:
================================

Post by Phil Allison
==============

** Really ????
That is massively ambiguous.
CC resistors can drop in value if they run hot and over time.
Mostly they slowly drift high, over a period of decades.
Crazy to crazy that " non linearity".

google resistor voltage coefficient

** Google " arrogant fuckwit " - see yourself described.

Carbons can be ballpark 100 PPM/volt.

** But are in fact not.

..... Phil

John Larkin

2022-03-08 01:16:50 UTC

On Mon, 7 Mar 2022 15:07:49 -0800 (PST), Phil Allison

Post by Phil Allison
================================

Post by Phil Allison
==============

** Really ????
That is massively ambiguous.
CC resistors can drop in value if they run hot and over time.
Mostly they slowly drift high, over a period of decades.
Crazy to crazy that " non linearity".

google resistor voltage coefficient

** Google " arrogant fuckwit " - see yourself described.

Carbons can be ballpark 100 PPM/volt.

** But are in fact not.
..... Phil

Comps can be 200.

In a tube amp with, say, a 50 volt p-p swing, that could be 10000 PPM
gain change, 1% distortion. That's almost enough to hear.

--
If a man will begin with certainties, he shall end with doubts,
but if he will be content to begin with doubts he shall end in certainties.
Francis Bacon

Phil Allison

2022-03-08 02:41:01 UTC

John Larkin bullshitted as usual wrote:
================================

Post by John Larkin

Post by Phil Allison
==================

** Really ????
That is massively ambiguous.
CC resistors can drop in value if they run hot and over time.
Mostly they slowly drift high, over a period of decades.
Crazy to crazy that " non linearity".

google resistor voltage coefficient

** Google " arrogant fuckwit " - see yourself described.

Carbons can be ballpark 100 PPM/volt.

** But are in fact not.

Comps can be 200.

** Bullshit

Post by John Larkin
In a tube amp with, say, a 50 volt p-p swing, that could be 10000 PPM
gain change, 1% distortion.

** Made up, absolute crap !!!!
-----------------------------------------------
-----------------------------------------------

Just to refute JL's rampant insanity - I carried a test:
With a sine wave at 1KHz feeding a small toroidal supply tranny in reverse.
Max available = 250Vrms at 0.05% THD.

A pair of MF resistors ( 100k and 1k ) in series showed only residual THD across the 1k.
Change the 100k to a ( very old ) 0.5W CC and the THD reading was then 0.33%
Drop the input level to 50V rms and the reading was 0.07%.

250V rms = 705 V p-p.
50V rms = 141V p-p.

FYI

One cannot test the * lineartiy * using DC voltages.
Cos the damn things heat and drop value by several %.

..... Phil

j***@highlandsniptechnology.com

2022-03-08 10:46:38 UTC

On Mon, 7 Mar 2022 18:41:01 -0800 (PST), Phil Allison

Post by Phil Allison
================================

Post by John Larkin

Post by Phil Allison
==================

** Really ????
That is massively ambiguous.
CC resistors can drop in value if they run hot and over time.
Mostly they slowly drift high, over a period of decades.
Crazy to crazy that " non linearity".

google resistor voltage coefficient

** Google " arrogant fuckwit " - see yourself described.

Carbons can be ballpark 100 PPM/volt.

** But are in fact not.

Comps can be 200.

** Bullshit

Post by John Larkin
In a tube amp with, say, a 50 volt p-p swing, that could be 10000 PPM
gain change, 1% distortion.

** Made up, absolute crap !!!!
-----------------------------------------------
-----------------------------------------------
With a sine wave at 1KHz feeding a small toroidal supply tranny in reverse.
Max available = 250Vrms at 0.05% THD.
A pair of MF resistors ( 100k and 1k ) in series showed only residual THD across the 1k.
Change the 100k to a ( very old ) 0.5W CC and the THD reading was then 0.33%
Drop the input level to 50V rms and the reading was 0.07%.
250V rms = 705 V p-p.
50V rms = 141V p-p.
FYI
One cannot test the * lineartiy * using DC voltages.
Cos the damn things heat and drop value by several %.
..... Phil

I said "comps", meaning carbon composition. We were talking about
carbon resistors.

--
I yam what I yam - Popeye

whit3rd

2022-03-08 02:34:36 UTC

Carbon resistors are semi-metals, so they get recombination noise;

Not sure what you mean by that, exactly. To get recombination noise you
need minority carriers, no?

probably the 'cermet' is a similar material.

Cermets aren't homogeneous--as the name implies, they're ceramic/metal
composites.

Semi-metals are semiconductors, but at or near their intrinsic temperatures.
A bunch of metal shavings in a tube, if shaken, has enough Shottky rectification
at the contact points to be an RF detector (coherer was the antique radio term).
Ceramics or metal oxides, with metal, are going to have minority carriers.
At each metal connection, you get carrier injection.

For metal film, though, it's terribly difficult to get a thin and
long continuous metal path for high resistance,

AND keep it from oxidizing and changing value. > So, carbon (carbon
film?) still is the solution for high-ohms items.

Carbon resistors, especially in presence of ozone, drift to higher values
because the carbon slowly turns to CO or CO2. Metals also grow oxide skins
(some more quickly than others). Substrate, metal, and glaze (or at least lacquer) plus
two solderable connections... a complete surface mount resistor packs a lot of
engineering into that little package.

John S

2022-03-08 03:18:05 UTC

Post by John Larkin
On Mon, 7 Mar 2022 12:35:32 -0500, Phil Hobbs

Post by j***@highlandsniptechnology.com
On Mon, 7 Mar 2022 12:03:17 -0500, Phil Hobbs

...gizmo was exhibiting horrific 1/f noise on the spectrum
analyzer. It turned out to be the classic Tektronix 50-ohm 2-W
BNC feedthrough terminator I was using--it was made of cermet.
Switching to metal film dropped the 1/f noise by about two orders
of magnitude IIRC. Not subtle at all.

It's probably too late, but it would be interesting to measure the
1/f noise vs current. It might be square law, namely thermal.

Nah, definitely linear, and definitely 1/f not 1/f**2. A
constant-rate drift notionally has a spectrum that goes as 1/f**4,
and a random-walk drift ('brown noise') goes as 1/f**2.

Carbon resistors are semi-metals, so they get recombination noise;

Not sure what you mean by that, exactly. To get recombination noise you
need minority carriers, no?

probably the 'cermet' is a similar material.

Cermets aren't homogeneous--as the name implies, they're ceramic/metal
composites.

For metal film, though, it's terribly difficult to get a thin and
long continuous metal path for high resistance,

AND keep it from oxidizing and changing value. > So, carbon (carbon
film?) still is the solution for high-ohms items.

It's certainly true that it's harder to make very high resistances out
of very low resistance materials, and there are lots of low-precision
applications where 1/f noise is not a serious issue--overvoltage
protection, for instance.
However, carbon resistors are seriously nonlinear at high voltages--the
resistance of old style Allen-Bradley carbon comps was allowed to drop
by a quarter at their upper voltage limit.
Cheers
Phil Hobbs

Yes! I learned that the hard way. Decided I was gonna make my own HV
divider from a string of 22meg CC resistors. I was astonished by the
change in resistance with voltage. So I made a new scale for the meter.

j***@highlandsniptechnology.com

2022-03-08 10:51:09 UTC

Post by John S

Post by John Larkin
On Mon, 7 Mar 2022 12:35:32 -0500, Phil Hobbs

Post by j***@highlandsniptechnology.com
On Mon, 7 Mar 2022 12:03:17 -0500, Phil Hobbs

...gizmo was exhibiting horrific 1/f noise on the spectrum
analyzer. It turned out to be the classic Tektronix 50-ohm 2-W
BNC feedthrough terminator I was using--it was made of cermet.
Switching to metal film dropped the 1/f noise by about two orders
of magnitude IIRC. Not subtle at all.

It's probably too late, but it would be interesting to measure the
1/f noise vs current. It might be square law, namely thermal.

Nah, definitely linear, and definitely 1/f not 1/f**2. A
constant-rate drift notionally has a spectrum that goes as 1/f**4,
and a random-walk drift ('brown noise') goes as 1/f**2.

Carbon resistors are semi-metals, so they get recombination noise;

Not sure what you mean by that, exactly. To get recombination noise you
need minority carriers, no?

probably the 'cermet' is a similar material.

Cermets aren't homogeneous--as the name implies, they're ceramic/metal
composites.

For metal film, though, it's terribly difficult to get a thin and
long continuous metal path for high resistance,

AND keep it from oxidizing and changing value. > So, carbon (carbon
film?) still is the solution for high-ohms items.

It's certainly true that it's harder to make very high resistances out
of very low resistance materials, and there are lots of low-precision
applications where 1/f noise is not a serious issue--overvoltage
protection, for instance.
However, carbon resistors are seriously nonlinear at high voltages--the
resistance of old style Allen-Bradley carbon comps was allowed to drop
by a quarter at their upper voltage limit.
Cheers
Phil Hobbs

In a divider made from a string of identical resistors, the
nonlinearity cancels. That's why the best dividers are all on the same
substrate.

--
I yam what I yam - Popeye

John Walliker

2022-03-08 11:46:03 UTC