ResMed's EasyBreathe -- What a Difference

jdm2857 wrote:

-SWS wrote:But that better-controlled servo loop, in and of itself, would actually provide a much straighter or flatter 10cm pressure delivery at the impeller's output if EPR were turned off and no other EasyBreathe control logic features were turned on.

The EasyBreathe control logic employs yet additional wave template control to make the pressure output more friendly to human stretch receptors.

If the pressure delivered is straighter or flatter with EasyBreathe off, the the pressure is less straight (or flat) with EasyBreathe on.

In other words, EasyBreathe causes pressure variations, no?

Lets look at another aspect.

Assuming the pressure (SWS says it is maintained at the impeller, I believe it is maintained at the pressure transducer which is at the air exit port) remains constant, then the flow will vary - as you breathe out you are pushing against the 10 CMs being fed in & as you explained before the pressure transducer detects a change in pressure at the air exit port & lowers the blower speed - this control in older models was not exactly precise - but then as you breathe in the flow swings back strongly towards you the user.

So in this perspective we are seeing significant fluctuations in the flow while the pressure remains relativle constant at the air exit port.

SWS has pointed out that while the pressure in one part of the system (human connected by a 6 foot tube to a fluctuating pump) can remain constant, it won't neccesarily be the same at the other end of the system at that point in time. It can vary by 2-3 CMs in this particular description (at 10 CMs pressure).

DSM

Hey, TwoKatMew!! THANK YOU for getting back to us about your Spontaneous and CPAP mode results!!!! You are NUMBER 15 that I now know about. RESMED ARE YOU READING AND HEEDING??? FIFTEEN VPAP Auto or VPAP Auto 25 experiencing abrupt pressure transitions in Spontaneous mode but the promised easy breathing in Auto mode.

dsm wrote:

jnk wrote:I think the ResMeds apparently needed, badly, an improvement in their pressure relief. I found the transition abrupt in my VPAP III, and Slinky finds the transition abrupt in Spontaneous mode in her VPAP Auto (which I assume has no Easy-Breathe in that mode) ... Does anyone think that the future may bring a machine that perfectly matches up pressure to a patient's individual flow pattern of breathing? Now that would be real comfort, I assume! And maybe it will come from a company that can give the big two a run for their, uh, money.

But I am getting the feeling that the smaller companies are falling by the wayside & that Resmed & Respironics are effectively dominating the market.

Respironics has gone global which really happened when Pilips took them on board. Resmed started out in Asia/Pacific, US UK & also set up in Europe.

With Coviden/Sandman now taken over by who ? it becomes a bit of a worry as to will survive. Weinmann still look good in Europe but unless they can get into the global market with competitive home cpap devices they may go the way of the others.

I fear we are seeing the emergence of a 2 horse race in home cpaps (at least for say next 5 years or so).

DSM

Yea, but, dsm - you've gotta keep in mind that DeVilbiss has finally smartened up and come out w/a fully data capable C and APAP. Fisher & Paykel have finally smartenend up and come w/a fully data capable C and APAP. Covidien/PB has come out w/a NEW LINE of fully data capable C and APAPs. There IS HOPE!!

We need to do our part and help educate newbies and HOPEFULLY reach them BEFORE they are past that first 30 days of pawned off bare bone CPAPs - and even earlier. Spread the word about cpaptalk.com, the other apnea support forums and cpap.com Go to some local apnea support group meetings. Never mind how boring some of them are! Stir the pot! Bring some life to their party, er, meeting.

dsm wrote:Assuming the pressure (SWS says it is maintained at the impeller, I believe it is maintained at the pressure transducer which is at the air exit port) remains constant, then the flow will vary - as you breathe out you are pushing against the 10 CMs being fed in & as you explained before the pressure transducer detects a change in pressure at the air exit port & lowers the blower speed - this control in older models was not exactly precise - but then as you breathe in the flow swings back strongly towards you the user.

Well, generally, all feedback transducers are calibrated so that system output is what is being accurately read by that feedback transducer.

In the various patent descriptions system-output pressure is usually referenced at either the mask or at the machine. In that latter case, machine-side output is typically referenced as impeller output by patent descriptions. So the transducer can be calibrated for that system-side output typically referenced at the impeller whenever proximal sensing at the mask is not employed. Still, there's a negligible pressure gradient or loss between those two near-points in the system (the feedback transducer and impeller near points).

DSM wrote:SWS has pointed out that while the pressure in one part of the system (human connected by a 6 foot tube to a fluctuating pump) can remain constant, it won't neccesarily be the same at the other end of the system at that point in time. It can vary by 2-3 CMs in this particular description (at 10 CMs pressure).

Well, that's a very good point. That's kind of the "middle point"---with the human diaphragm at one far end contributing pressure, and the CPAP impeller at the other far end also contributing pressure.

Each of those far-end contributors will incur a pressure gradient or gradual loss toward that middle point. We might want to let the thought just ruminate in our minds a bit---that we used to have only the diaphragm (of those two) before we went on CPAP. Let's also take note of what the pressures used to be at our mouths back then: if we had measured those pressures at the mouth, we would have measured alternating positive and negative pressures...

Enter CPAP and its highly descriptive acronym: it's a Continuous Positive Air Pressure machine. Two characteristics about the machine's delivery pressure worth noting are that it's both continuous and positive---despite our respiration still requiring that our airway pressures alternate with respect to atmospheric pressure. But that "continuous positive" part of the acronym describes what happens back at the machine's system output side---not what the alternating pressures happen to be inside the human airway. Inside the human airway we still need to alternate between negative and positive pressures if we expect to alternately reverse our airflow so that we breathe both in and out.

So despite that machine continuously sourcing positive-pressure at the impeller, the pressure at the mask is going to be a resultant of both pressure-delivering contributors and their respective gradient inefficiencies or losses along the way toward that middle point (with the respiratory drive now adapting a bit as it factors CPAP's inspiratory assistance and expiratory back pressure). The human diaphragm is really the biggest pressure-delivering contributor between those two. Despite a CPAP impeller maintaining a constant delivered pressure at its far end, the human diaphragm is going to cause mask pressure to go positive during inhale and negative during exhale (referenced at the machine---reverse that if you want to reference at the diaphragm). Reference it where the airway used to collapse, and you have a bit of extra positive stenting pressure (thanks to the CPAP machine) that now holds the airway open.

_____________________________________________________________________________________

Anyway, Resmed EasyBreathe is going to deliver nothing but positive pressures, even if EPR or BiLevel is turned on. But at least with EPR turned on, EasyBreathe at least has a positive-pressure differential between IPAP and EPAP with which to mimic the alternating pressures provided by the human diaphragm. If you leave EPR turned off, then you have a lot less pressure differential to mimic.

When this thread relied on abstract terms only to describe EasyBreathe's "natural" pressure variations, that qualitative description left almost no reason to have an EPR=off ("CPAP modality") and EPR=on (intermittent "Bilevel modality"). Once you get to placing those abstract or qualitative terms aside, and work the quantitative end a bit, you're stuck with the realization that: 1) that machine will never alternate positive and negative pressures as the human diaphragm would, 2) it's a positive-pressure template that the system targets by design, and 3) you have to move that positive pressure up and down to mimic human respiration (thus that mimicking fares better with EPR on---since you need some pressure leeway to move those pressures up and down for that natural mimicking act).

The best that machine's design can do with BiLevel disabled (EPR=off) is probably to work on that front-edge expiratory pressure transition by: 1) avoiding additive pressure spikes (via a more tightly controlled servo loop in the time domain), and/or briefly drop the pressure during that front-edge of the human inhale-to-exhale transition. That last technique is what patented C-Flex does. There may or may not be room for a patent-infringement in court if Resmed employs that softening during that same leading-edge transition...

But making the curve nice and gradual during BiLevel or EPR=on moments, is a more difficult patent-infringement beef IMO. That's why I initially thought that Resmed may have reserved all EasyBreathe techniques (except a tightly-controlled servo loop) strictly for BiLevel modality. Regardless, they may very well be softening that same leading-edge expiratory transition in CPAP mode as Respironics does---only better perhaps.

What does jdm2857 win if he has discovered a patent infringement, being the first to notice that ResMed may have sneaked in a copy of Respironics-style pressure relief under the radar with all their verbal hocus-pocus in their advertising?

Or . . .

Does this mean we should all just walk away from this thread very quietly as if it never happened?

Jeff, it may be time for you to enter the cpaptalk-witness-protection program before ResMed comes looking for you, man. Don't use your credit card, and be sure to remember to take the battery and sim card out of your cell phone, and just keep moving.

-SWS wrote:

dsm wrote:Assuming the pressure (SWS says it is maintained at the impeller, I believe it is maintained at the pressure transducer which is at the air exit port) remains constant, then the flow will vary - as you breathe out you are pushing against the 10 CMs being fed in & as you explained before the pressure transducer detects a change in pressure at the air exit port & lowers the blower speed - this control in older models was not exactly precise - but then as you breathe in the flow swings back strongly towards you the user.

Well, generally, all feedback transducers are calibrated so that system output is what is being accurately read by that feedback transducer.

In the various patent descriptions system-output pressure is usually referenced at either the mask or at the machine. In that latter case, machine-side output is typically referenced as impeller output by patent descriptions. So the transducer can be calibrated for that system-side output typically referenced at the impeller whenever proximal sensing at the mask is not employed. Still, there's a negligible pressure gradient or loss between those two near-points in the system (the feedback transducer and impeller near points).

<snip>

Steve,

I believe that the new EasyBreathe motor/blower in the Resmeds acts as an air buffer between the pressure transducer at the exit port and the pressure being generated by the motor/blower. Probably not that big a deal but Resmed point out that the fan inflates the motor/blower casing & that inflated 'balloon' holds air in a pressurized bag. There is going to be a skew between the pressure in that bag & what the pressure transducer senses. That was why I always referred to sensing the pressure at the air exit port (which all machines do).

Doug

-SWS wrote:
<snip>

DSM wrote:SWS has pointed out that while the pressure in one part of the system (human connected by a 6 foot tube to a fluctuating pump) can remain constant, it won't neccesarily be the same at the other end of the system at that point in time. It can vary by 2-3 CMs in this particular description (at 10 CMs pressure).

Well, that's a very good point. That's kind of the "middle point"---with the human diaphragm at one far end contributing pressure, and the CPAP impeller at the other far end also contributing pressure.

Each of those far-end contributors will incur a pressure gradient or gradual loss toward that middle point. We might want to let the thought just ruminate in our minds a bit---that we used to have only the diaphragm (of those two) before we went on CPAP. Let's also take note of what the pressures used to be at our mouths back then: if we had measured those pressures at the mouth, we would have measured alternating positive and negative pressures...

Enter CPAP and its highly descriptive acronym: it's a Continuous Positive Air Pressure machine. Two characteristics about the machine's delivery pressure worth noting are that it's both continuous and positive---despite our respiration still requiring that our airway pressures alternate with respect to atmospheric pressure. But that "continuous positive" part of the acronym describes what happens back at the machine's system output side---not what the alternating pressures happen to be inside the human airway. Inside the human airway we still need to alternate between negative and positive pressures if we expect to alternately reverse our airflow so that we breathe both in and out.

##DSM: Absolutely the CPA 'pressure' is applied to stent the airway open, but the flow of air can change markedly whilst this pressure is maintained (at the air exit port). The wave shaping is not pressure alone but flow & rate of flow. Technically it is possible for the user to blow into the hose & have the airflow going into the cpap all the time the pressure transducer says "I can see 10 CMs of pressure, while I ignore the flow volume & direction". Naturally we don't really want users blowing down their airhoses. The cpap machines doesn't have OSA

So despite that machine continuously sourcing positive-pressure at the impeller, the pressure at the mask is going to be a resultant of both pressure-delivering contributors and their respective gradient inefficiencies or losses along the way toward that middle point (with the respiratory drive now adapting a bit as it factors CPAP's inspiratory assistance and expiratory back pressure). The human diaphragm is really the biggest pressure-delivering contributor between those two.
##DSM: Absolutely, it has to (on exhale) exceed the delivered pressure & expel air.

Despite a CPAP impeller maintaining a constant delivered pressure at its far end, (###DSM: yes but not constant flow rate.) the human diaphragm is going to cause mask pressure to go positive during inhale (###DSM: ? - I would have said negative as the pressure relieves itself into the lungs with the aid of the diaphram) and negative during exhale (referenced at the machine---reverse that if you want to reference at the diaphragm). (###DSM: am lost here ?, surely during exhale the mask pressure goes positive & this is when leaks & seal pops are most likely to occur. The users exhalation pressure and flow pushes down the airhose into the machine against the pumped air and causes the air exit transducer to signal a slowdown of the blower) Reference it where the airway used to collapse, and you have a bit of extra positive stenting pressure (thanks to the CPAP machine) that now holds the airway open.

_____________________________________________________________________________________

Anyway, Resmed EasyBreathe is going to deliver nothing but positive pressures, even if EPR or BiLevel is turned on. But at least with EPR turned on, EasyBreathe at least has a positive-pressure differential between IPAP and EPAP with which to mimic the alternating pressures provided by the human diaphragm. If you leave EPR turned off, then you have a lot less pressure differential to mimic.

When this thread relied on abstract terms only to describe EasyBreathe's "natural" pressure variations, that qualitative description left almost no reason to have an EPR=off ("CPAP modality") and EPR=on (intermittent "Bilevel modality"). Once you get to placing those abstract or qualitative terms aside, and work the quantitative end a bit, you're stuck with the realization that: 1) that machine will never alternate positive and negative pressures as the human diaphragm would, 2) it's a positive-pressure template that the system targets by design, and 3) you have to move that positive pressure up and down to mimic human respiration (thus that mimicking fares better with EPR on---since you need some pressure leeway to move those pressures up and down for that natural mimicking act).

The best that machine's design can do with BiLevel disabled (EPR=off) is probably to work on that front-edge expiratory pressure transition by: 1) avoiding additive pressure spikes (via a more tightly controlled servo loop in the time domain), and/or briefly drop the pressure during that front-edge of the human inhale-to-exhale transition. That last technique is what patented C-Flex does. There may or may not be room for a patent-infringement in court if Resmed employs that softening during that same leading-edge transition...

But making the curve nice and gradual during BiLevel or EPR=on moments, is a more difficult patent-infringement beef IMO. That's why I initially thought that Resmed may have reserved all EasyBreathe techniques (except a tightly-controlled servo loop) strictly for BiLevel modality. Regardless, they may very well be softening that same leading-edge expiratory transition in CPAP mode as Respironics does---only better perhaps.

SWS again thanks for raising such interesting issues & points. DSM

dsm wrote:

-SWS wrote:

dsm wrote:Assuming the pressure (SWS says it is maintained at the impeller, I believe it is maintained at the pressure transducer which is at the air exit port) remains constant, then the flow will vary - as you breathe out you are pushing against the 10 CMs being fed in & as you explained before the pressure transducer detects a change in pressure at the air exit port & lowers the blower speed - this control in older models was not exactly precise - but then as you breathe in the flow swings back strongly towards you the user.

Well, generally, all feedback transducers are calibrated so that system output is what is being accurately read by that feedback transducer.

In the various patent descriptions system-output pressure is usually referenced at either the mask or at the machine. In that latter case, machine-side output is typically referenced as impeller output by patent descriptions. So the transducer can be calibrated for that system-side output typically referenced at the impeller whenever proximal sensing at the mask is not employed. Still, there's a negligible pressure gradient or loss between those two near-points in the system (the feedback transducer and impeller near points).

<snip>

Steve,

I believe that the new EasyBreathe motor/blower in the Resmeds acts as an air buffer between the pressure transducer at the exit port and the pressure being generated by the motor/blower. Probably not that big a deal but Resmed point out that the fan inflates the motor/blower casing & that inflated 'balloon' holds air in a pressurized bag. There is going to be a skew between the pressure in that bag & what the pressure transducer senses. That was why I always referred to sensing the pressure at the air exit port (which all machines do).

Doug

Well, that inflationary chamber affect you mentioned also happens to be a fixed function relative to raw transducer readings. It's not a constant---but it's a fixed function and thus easy to algorithmically factor in any measurement calculations.

Why would the transducer in that particular feedback loop provide any kind of insurmountable challenge in the algorithm coming up with an accurate system output measurement? The algorithm would only need to offset that raw transducer data with nothing more than a fixed-function calculation to know what the system's output is at the blower.

Again, feedback loop transducer's are supposed to provide measurements about the system or subsystem's output. And I don't see that purely fixed-function inflationary chamber posing any kind of a problem in algorithmically ascertaining (i.e. "measuring") system output. No point in tossing highly standard system feedback out the window because of a little inflationary chamber that does the same exact thing in physics every time you inflate it.

Okay, once again we disagree on a whole lot of points. Not the first time... Thanks for your views as well.

You 2 are hilarious...and educational; hey folks, it's the Steve & Doug disagreement hour...would that we are were so civil! Thanks! I so enjoy these..ahem, little discussions that stretch my remaining functional brain cells to the limit

Muse-Inc wrote:You 2 are hilarious...and educational; hey folks, it's the Steve & Doug disagreement hour...would that we are were so civil! Thanks! I so enjoy these..ahem, little discussions that stretch my remaining functional brain cells to the limit

And I'm glad -SWS has his monkey glasses on again...that is my favorite avatar of him.

Somewhere in here (meaning the myriad of threads about Resmed and other machine algorithms) is the explanation for why my Autoset, in APAP mode, doesn't respond to my hypopneas/apneas. I just don't understand it yet though, apparently.

mar

Well please enjoy it! That last exchange was academic to the point of being outlandish.

Inflationary chamber or not, the transducer sits right at the impeller's output side---very close to where the CPAP hose plugs in. To even claim that the raw transducer data somehow doesn't accurately measure system output because of a slightly inflationary chamber is objecting to teensie-weensie transient pressure discrepancies not even supported by that pressure-delivery circuit. Sensing teensie pressure pulsation signals like cardiogenic oscillations toward making treatment decisions is one thing... But measuring much more coarse pressure-delivery circuit output is another thing entirely---that doesn't come even close to supporting such small pressure signal feedback resolutions required to measure the transient deltas between the impeller's output and feedback transducer.

And for me to entertain a comment about transient pressure discrepancies at such small and circuit-irrelevant resolutions is academic entertainment of an impractical objection. If you need to measure system output by compensating raw transducer data with a simple fixed function, then that's what you do. Here, the raw transducer data measures the system's pressure output just fine given the typical resolutions at which these circuits work.


Silly academic debate for objections based on irrelevant resolutions that are way too small to even matter for this feedback control circuit...

-SWS wrote:Well please enjoy it! That last exchange was academic to the point of being outlandish.

Inflationary chamber or not, the transducer sits right at the impeller's output side---very close to where the CPAP hose plugs in. To even claim that the raw transducer data somehow doesn't accurately measure system output because of a slightly inflationary chamber is objecting to teensie-weensie transient pressure discrepancies not even supported by that pressure-delivery circuit. Sensing teensie pressure pulsation signals like cardiogenic oscillations toward making treatment decisions is one thing... But measuring much more coarse pressure-delivery circuit output is another thing entirely---that doesn't come even close to supporting such small pressure signal feedback resolutions required to measure the transient deltas between the impeller's output and feedback transducer.

And for me to entertain a comment about transient pressure discrepancies at such small and circuit-irrelevant resolutions is academic entertainment of an impractical objection. If you need to measure system output by compensating raw transducer data with a simple fixed function, then that's what you do. Here, the raw transducer data measures the system's pressure output just fine given the typical resolutions at which these circuits work.


Silly academic debate for objections based on irrelevant resolutions that are way too small to even matter for this feedback control circuit...

???

C'mon Steve - What I was writing about is flexible chamber will skew the readings ???. Did I not highlight that pressure can remain constant but flow can go from one direction to another. Talking about pressure & ignoring flow is not taking all the relevant data into account. I think it is common sense that the flow is going to always be from machine to user but it will fluctuate significantly. Doesn't an air balloon contain a flexible pocket of air. Also the original point was that air measurement is taken at the air exit port and I see you agree with that. There are losses as air flows, between any two points in the air circuit.

DSM

#2 hey its interval - where is the peanut seller ???

Alright, Doug. Recent points well taken... so cheers!

-SWS wrote:Alright, Doug. Recent points well taken... so cheers!

Cheers Steve

DSM