F-14AM - The Iranian Tomcat - History, Performance, and Discussion

this only goes up to mach 1 where drag is a lot higher than if you were going faster

" The value of the drag-divergence Mach number is typically greater than 0.6; therefore it is a transonic effect. The drag-divergence Mach number is usually close to, and always greater than, the critical Mach number. Generally, the drag coefficient peaks at Mach 1.0 and begins to decrease again after the transition into the supersonic regime above approximately Mach 1.2."

Drag-divergence Mach number - Wikipedia.

yes its Wikipedia but I’m just a dumbass that knows a bunch of random things

Drag is proportional to velocity squared

You can do the maths yourself. I used the frontal area of an AIM-54 with the drag coefficient of a G7 projectile at 1475 m/s with an air density of .092 kg/m^3 at 18,000 meters. I got 22107 Newtons. If you try the same at 7800 m/s at 120,000 meters I got 4978 Newtons. It’s around 4 times more drag at 15 percent the altitude and 19 percent the speed.

The fact that the guy @sudo_su1 is arguing with honestly said that 44 m/s^2 is “near zero” for his “maths” to be considered correct is hilarious.

The math is still correct and valid, the resultant number just hasn’t been corrected for drag. You guys saying it’s invalid doesn’t make it invalid - if math is invalid it would be something you could show… mathematically.

Now if we could all hop off the insult train and focus on proving / disproving the motor has 290+ seconds specific impulse we’d be getting somewhere. They’re currently waiting on @sudo_su1 to email NASA back and ask them how they derived the average thrust and what data was used.

AIM-23C Sedjeel ground separation tests (In the 80s during Iran-Iraq war)

After a lot of digging, this might be the test firing footage of an actual Fakour missile with boost-sustain motor (rather than the sustainer-only AD-40A export variant/offering, footage of which often circulates as “Fakour test launch” where the pilot uses the “Fox 1” code during missile launch)

This is sustainer-only AD-40A export variant/offering for comparison:

And this is the AIM-54A for comparison:

The perspectives are all a bit different, but I think the difference in acceleration is still obvious.

@MiG_23M I’ve sent a bunch of emails (To both NASA and Aerojet’s parent company L3Harris). I will let you know if they answer.

Safe to say that they launch a bunch of these things:

image1314×1563 288 KB

Also also:

image1198×889 180 KB

I’m pretty sure he’s taking drag into account though ;)

@MiG_23M @Gunjob

There is also a 2015 edition of the “NASA sounding rockets user handbook” and it provides different figures than both 2005 and 2023 editions.

2005 edition:
19000 lb @ 4s + 3000 lb @ 21s

2015 edition:
20000 lb @ 6s + 4000 lb @ 19s

2023 edition:
20000 lb @ 6s + 4000 lb @ 18s

So as you can see, this is a very high quality source that every few years, with each new edition, refines and revises the thrust figures that it provides, based on the expanded data set and improvements in measurement and calculation accuracy (of velocity and altitude and drag etc).

And that’s besides the fact that this is also the ONLY publicly available source that gives thrust figures for this motor. (Other than the test launch study that I linked in the section C of the main post in the bug report that gives average thrust for the whole burn time)

(Regarding this report: https://community.gaijin.net/issues/p/warthunder/i/EaLuXWmNnW4F )

This just looks like the latest launch data was used and the performance of the motor varies quite a bit (as expected from that older propellant).

As you know, the other sources I initially shared with acceleration over time shows the thrust indirectly. Gaijin has been known to use this as additional source material for confirming other datapoints in the past and they should definitely look into it here as well.

As I just showed here, they launch many of these each year, so they have a very large sample size. Way larger than that one singular European launch that you are trying to use to guesstimate thrust from, without even taking drag into account or knowing the vehicle’s mass at each point in time.

And no, old propellant doesn’t cause a 38% increase in total impulse. That’s just not how rockets work.
Less accurate measurements or underestimation of drag does …

As I and others have pointed out already, that source is virtually useless for calculating thrust.

Plus, one singular launch is essentially noise compared to NASA’s data which is based on many many launches.

Not only is expired propellant a possible reason - it is the most likely reason the total impulse changed so drastically.

There are few other reasons explaining the discrepancy with such high likeliness. I already shared a document showing that certain batches of the motor had unbonding issues.

You and others can remain incorrect

That is your assumption, that they base the date on many launches. I would think that with such a large datapool as early as 2006 that the values would not change so drastically year to year unless the tolerances and performance of the motor varies so wildly.

If the values from the 2005 edition of the handbook (which result in a lower total impulse) were due to poorly aged motor it’s all the more reason to use the newer, revised and more refined values from the 2023 edition of the handbook that are based on the expanded data set / larger sample size.

Let me just sum up what you’ve done on this topic so far.
“My math for figuring out thrust where I don’t take drag into account and also have no clue what the mass is of the object my sustainer is powering is actually always correct and everyone else is always wrong and biased. Also @sudo_su1 your sources aren’t average thrust. You’re wrong. simple as.”
NASA: “They’re average thrust.”
“Well then they were launched at altitudes in this particular case.”
NASA: “They’re ground launched.”
“Well then there were different atmospheric conditions. Also NASA did their calculations wrong. My single sample size and napkin algebra is better than all of NASA’s launches and their team’s calculus combined.”

You’ve done nothing but endlessly argue completely ridiculous points from a baseless position. For the benefit of everyone just never comment again.

Sudo pushed a report before all the facts were at hand and before all the questions could be asked. He has since revised his post dozens of times with new information and for some odd reason, only the information that agrees the missile should be buffed. This is a cue for speculation imo. Dismissing useful information when it doesn’t agree with you is NOT proper reporting etiquette.

The ROTEX-T launch mass is known, in fact they broke down the components for us as well. The drag can be found by Gaijin rather easily as the rocket uses a very simple shape and the deceleration post-burn of the initial booster stage (PRIOR to M112 ignition) gives us a solid base from which to ascertain the true drag coefficient of the rocket.

Not only that, none of the NASA sources have a true thrust over time chart to go off of. Gaijin can use the various average thrusts from the NASA source in conjunction with the thrust profile provided by the ROTEX launch to find the true minimum and peak thrusts as well as determine how they want to translate that into the game.

You want to paint my bickering as baseless but instead what you’ve done is come in here with an unwarranted spiteful insult and added precisely nothing to the thread or conversation. If anyone was to see themselves out, it’s you… but this is a public forum so we’ll all just have to suffer with each other won’t we?

@sudo_su1 pending NASA’s reply about how they found the “average” thrust… I’m sure they put a lot more effort into it than this but as an example…

How many times did they sample the thrust value? At what intervals? Did they take absolute peak and absolute minimum to divide by 2? Without knowing how they came up with the data our best bet is to assume it is well-sampled and apply the average to the thrust curve shown in the ROTEX-T source.

Specific impulse and burn rate isn’t constant, so in order to calculate thrust from acceleration you need to also estimate / calculate vehicle’s mass (which includes the mass of the remaining propellant) at each point in time.
Good luck with that with the amount of info that the ROTEX-T study provides.

And actually, the very fact that the authors of the ROTEX-T study themselves didn’t even try to calculate and provide a thrust figure, shows that they understood that they don’t have enough data to do so.

There’s no need.
All you need is booster burn time * average thrust and sustainer burn time * average thrust
That’s all that WT models anyways.

Plus, how many of the rocket motors that we have in the game have actual thrust charts?! :)

The idea that a single launch in Europe where the authors themselves didn’t bother with calculating the thrust figures most likely because they understood that they don’t have enough data to do so, is a better source than NASA’s reference handbook that has been refined and revised over many many years using the data from many many launches, is absurdly childish.

We know the weight of the initial booster section, the payload, the weight of the M112 rocket motor section. Subtract the initial booster and then it’s as simple as determining boost - sustainer mass fraction.

Adjusting the weight at booster burn-end using the average thrust values in this chart until we have a reasonable ISP for both booster and sustainer gives us reasonably correct values and propellant burn rates.

image1366×664 123 KB

From there it’s easy to determine how much mass is burned over time. The data is there, why are you so adamant to ignore it?

R-27ER, and even then it’s underperforming in top speed by 100 m/s at altitudes 5km+

Because that wasn’t the objective?

Certainly NASA’s handbook has an acceleration over time chart that shows us the exact thrust profile of the rocket motor? No? Then yes this source is 100% useful. Stop pretending it’s one or the other, it is both. All of these sources together. Not just one. Quit dismissing useful data.

Your best friend ranting about my math and providing nothing useful to the convo was childish. Let’s not turn this into a slapping contest.

Devs responded about Fakour thrust
https://community.gaijin.net/p/warthunder/i/EaLuXWmNnW4F?comment=KhmvL8Y3rLGxArCHRfuLqUqh

What I didn’t realize - that the devs caught - is that the specific impulse of ~234s is given for the rocket type in one of the sources and explains that a specific singular type of propellant was assumed to be used for the approximation of the thrust values… leading to incorrect figures.

Simply put, it was not (and still isn’t possible) for a rocket with AP/Poly fuel to have nearly 300s specific impulse. The numbers in-game are much closer to the real values than the NASA sources (which approximated average PEAK thrust) are giving.

Yeah they responded without even properly reading the report!

Completely false argument due to the fact that they didn’t even read the article … They just searched “specific impulse” in the article and copy pasted the first number they found …

Refer to the section “3” in my next post.

But the TLDR of it is that this study literally takes the thrust figures from the 2005 edition of the NASA handbook and calculates the specific impulse off of that.

So of course the specific impulse will be in line with the thrust figures of the 2005 edition of the handbook! what a shocker!

Regarding this bug report: Community Bug Reporting System

Which was answered as “not a bug” by the developers, unfortunately, as is clear by the dev’s response they did not look into the evidence thoroughly:

1-

Таким образом, очевидно в этом источнике тут указаны пики тяги, средняя тяга за время горения РДТТ M112 значительно ниже.
Как выше я уже сказал это не корректные данные, вы аппроксимируете пиковую тягу на все время работы разгонной и маршевой ступени. Для РДТТ достижение суммарного импульса в 855kN при массе топлива в ~295кг не возможно, потребовался бы удельный импульс 2900м/с, чего у РДТТ не достижимо в условиях земной атмосферы.
Где в источнике сказано что это средняя тяга?
Это не более чем ваше предположение. Которое опровергается значением удельного импульса двигателя.

I have already emailed NASA and they confirmed that the values in the handbook are in fact average thrust, and not peak thrust:

Spoiler

Screenshot 2024-08-09 2010154000×1897 229 KB

Screenshot 2024-08-09 2009423999×1006 146 KB

And this is obvious anyways … Peak thrust is useless to the audience of the NASA rockets user handbook who are looking to choose an appropriate motor for their application. The source explicitly mentions “average thrust” for all other motors that are listed in the handbook. For the “Improved Orion” motor it uses the term “approximate thrust” because it doesn’t provide “exact” values i.e. to the first digit, like it does for other motors.

2-

Кроме того это противоречит источнику, который вы сами приложили к репорту:
Imgur: The magic of the Internet

The study in question is this:
REXUS 2 - the first EuroLaunch project
https://www.researchgate.net/publication/238585597_REXUS_2_-_the_first_EuroLaunch_project

This study is from 2005. And:
A- Does not provide any thrust figures.
B- There is no indication of what measurements were taken during flight. It does not even present any acceleration charts. The only thing it provides is, not even an actual flight trajectory chart, but a “predicted” flight trajectory chart.
C- The study explicitly specifies that the burn time given is not the actual burn time, but the “nominal” burn time:

So it’s obvious that the burn time mentioned in the study is a quote from other older sources (and is also close to what is mentioned in the 2005 edition of the NASA rockets user handbook). Not to mention that NASA’s 2023 rockets user handbook is a more recent source / edition and has revised information.

3-

Если считать что эти данные корректны то суммарный импульс тяги то получается (200006+4000 18) * 0.4536 * 9.81 = ~854364Н * с, что не возможно для РДТТ с массой топлива в ~290кг. В источнике который вы приложили указано что удельный импульс для этого РДТТ составляет 2305м/с
Imgur: The magic of the Internet

As for the specific impulse, the study that the devs are quoting here (Multidisciplinary optimisation of single-stage sounding rockets using solid propulsion) is not even a test launch study, but rather a simulation study.

And this study is not even simulating the propellant used in M112, but rather an alternative propellant based on other propellants that they had simulation models for (from other, different rocket motors):

a slightly modified propellant, closer in performance to the existing ones, was used
(specific impulse of 2305 m/s at launch at a maximum chamber pressure of 14 MPa, one type of propellant in the
SRM is assumed).

Moreover, this study itself, takes the thrust figures from the 2005 edition of the NASA rockets user handbook!:

Reference [33] highlighted in the screenshot above is (The Improved Orion section of) the 2005 edition of "NASA rockets user handbook".

And the source itself says:

(specific impulse of 2305 m/s at launch at a maximum chamber pressure of 14 MPa, one type of propellant in the
SRM is assumed

“is assumed”! is the key word here!

I.e. this study literally references and takes the thrust figures from the 2005 edition of the NASA handbook and calculates / assumes the specific impulse off of those values.
So of course the specific impulse calculated / assumed based on the thrust figures give in the 2005 edition of the NASA handbook will be in line with the thrust figures of the 2005 edition of the handbook! And lower than that of the 2023 edition of the same NASA handbook (which specifies higher thrust figures). What a shocker!

Moreover:

A- According to the 1960 patent by the manufacturer (Aerojet) which seems to be the first patent regarding AP/polyurethane propellants, it’s said that depending on the aluminum content, the specific impulse can range from 220 to 270 s at 1000 psia:

Solid propellant with polyurethane binder US3793099A
https://patents.google.com/patent/US3793099A/

B- Later, a 1963 patent by the manufacturer (Aerojet) increases this figure to about 300 s (for comparison, values given in the 2023 edition of the NASA rockets user handbook will result in an Isp of around 295.6 s):

Polyurethane propellant formulations and process US3291660A
https://patents.google.com/patent/US3291660A/

4-
Even if we assume that the actual specific impulse of the propellant can’t be that high, we already have motors such as that of AIM-7F that have in-game specific impulse values higher than “physically possible”.
The reason that the devs gave for this was that:

https://community.gaijin.net/issues/p/warthunder/i/RfdZe2n1F4OA
The over performing motor is intentional, when a missile’s motor is firing it will experience a reduction in drag compared to when motor is not firing. Since it is difficult to implement two different drag value, the dev decides to increase the thrust during the motor firing to simulate the drag reduction.

So it’s possible that the thrust values calculated in the 2023 edition of the NASA’s rockets user handbook are also high as a result of the drag reduction that happens due to the long burn time of the motor.
And if that’s the case, there is no reason as to why that shouldn’t be reflected in the game as well (just as it’s reflected for the AIM-7F by giving it specific impulses higher than “physically possible”).

5-

В этом источнике очевидно речь идет не о М112, т.к. для достижения импульса в 934720Н*с при массе топлива в 295кг потребовался бы удельный импульс 3168м/с, чего физически не возможно для РДТТ. Кроме того там указана одна тяга, это означает что используемый во второй ступени РДТТ однорежимный либо данные указаны не полные или вообще ошибочные.

The study in question is this:
A sounding rocket payload experiment on zero gravity fuel gauging using modal analysis
https://www.researchgate.net/publication/273308323_A_sounding_rocket_payload_experiment_on_zero_gravity_fuel_gauging_using_modal_analysis

Improved Orion is an off the shelf military surplus M112 motor used for space / sounding rocket applications as indicated by many studies.

There is no “sustainer-only Improved Orion / M112” motor.

The reason that only one thrust value and one burn time is given is because the researchers averaged the total impulse over the total burn time to calculate one overall average thrust over the whole burn time, without specifying each phase separately.

The reason that the specific impulse is so high is because here the M112 is burning as second stage, at very high altitude, which results in higher specific impulses.

But this confirms the burn time and average thrust figures that were revised in the 2023 edition of the NASA rockets user handbook, because, if the burn time for a second stage very high altitude burn is 25.4, it can’t be 26s for a first stage burn from the ground.

If you wrote smth in comments instead of report itself it can be easilly missed, especially if there is a long conversation between different players and not just tech mod and you.