One Factor that doesn't Limit my appreciation of this channel is Jordan's transparent willingness to admit what predictions he got wrong and why. In a world of influence and fakery, this is both factually invaluable and appreciated. Astonishing to me that the Channel doesn't have a million subscribers.

Amazing to see Tesla chose the correct form of cooling since the beginning in 2012. The power of first principle thinking.

Kudos to you for being transparent about being wrong in the past, and correcting it.

I recall Sandy Monroe stating, about a year or two ago, when the 4680 was first being mooted that he felt the power dissipation aspect of the 4680 was the most compelling part of the design, even before any particular chemistry. And this video supports that view.

Thanks once again for your insights. Surface area of contact with the thermal sink is the key determinant of sink efficiency. That makes sense. And the tabless design reduces resistance and thereby reduces point thermal spikes, thermal heterogeneity, and accelerated electrode failure.

Great video. I was also under the impression that plate cooling for cylindricals was the best approach. Also worth mentioning that teslas 4680's uses ~600 micron cell cans, which would greatly increase the thermal conductivity of the can itself

There is something soothing about your voice that it help me fall asleep in the evening 😅

Very interesting. I was under the impression that plate cooling was superior due to those plastic separators so the nuance is much appreciated.

Jordan your knocking out videos with the quickness! Love your stuff! Keep up the great work!

Along with the structural benefits of ribbon cooling and the fire mitigation benefits, it is just a much more feasible manufacturing task than assembling hundreds or thousands of cylindrical cells in a bottom cooled pack. Especially given the need for standard separations between cells and placement for the collector connections, it is just much easier to glue the cells to a ribbon cooling tube and make bandoliers then to place hundreds of loose cells into a pack precisely and try to assemble the pack from there without jostling them out of place or tipping them.

At @15:15 you state that the heat dropped by about 60%, which is correct based on the math shown. But at @15:30 you multiply by 0.6, which would be only a 40% reduction. You should have multiplied by 0.4, or divided by 1.6. The conclusion you reached was that heat losses come down from 5% to 3%. But the math would bear it out that you go from 5% to 2%. While that's a 1% difference, the difference between 2 and 3 is 50%. Great video so far, loving it always.

With higher amount of cycles for LFP + lower degradation due to better thermal management of the tables design these 4680 batteries will likely outlive other components of the car enabling reuse of battery packs in other cars and/or in future storage packs. While simultaneously giving more power as the shorter travel path of electrons enables higher current flow increasing the acceleration possibilities and also the charging speed possibilities. Looking forward to cars being charged at vastly shorter times without degrading them. Will likely be even more important for Semi & cybertrucks than current passenger models. Thank you for your very detailed in depth videos! This is braingasm for a chemical engineer 🤩🤓

Well done. Thanks Gordon. Regarding Thermal function of the top/bottom Plates. My take is because your Tested 4680 Cell was not used under pressure, in a car, prevents us from seeing the Actual affect of heating cycles. Hope that @Munrolive will dissect one.

Great video as always, appreciate the humility at the beginning further adding to your credibility. Look forward to your next videos!

Excellent stuff ! I had to specify and manage the battery "fleet" at a robot company. So batteries are eternally fascinating (to me !) . One thing I suspected, and AI2 sort of proved, is that Tesla's ability to model the real world is unrivalled ( nobody really mentions this rather important moat). That is a mix of software, mathematics, physics and engineering expertise, to model whatever they need to optimise - rather than rely on "expert opinion". What's interesting here is the "bias towards the proven result" - once you realise the reasons why side cooling is better - "Well it's obvious! "...(except it wasn't at the time...)

Thank you!

A very illuminating explanation... confirming also that Tesla's engineers considered all possible functions (thermal, electric, structural, ...) of every part in order to improove vehicle's efficiency...👍🤙

Great and educational video. Thank you Jordan for your hard work and dedication.

What a surprise ,I was sure it would be done at the copper anode end of the sell, it goes to show how clever Tesla truly is, Thanks for your update .

Thank you for all the work you do for the Tesla community 👍

Incredibly informative and easy to understand. I'm not a chemistry geek, so there are times when the explanation flew over my head. But overall, it confirms my faith in the 4680 battery, especially if the Tesla owner plans on keeping the car for a long time

Great video man. I wonder if this will be the long term or shorter term cooling solution. I would imagine it would continue to evolve as new silicon doping and material changes with v2, v3, etc if they are indeed serious about million mile battery. Also big congrats on closing in on 100k subs!!

It’s possible there is also another couple of benefits to ribbon cooling. The ribbons can act like a stiffener to the battery pack, providing internal support. This in turn reduces amplitude of vibrations, which in turn reduces forces acting on the battery connection. Ultimately providing better longevity of the pack. Where does this assumption come from? My first Job after school was as a sheet metal worker. Square ducting is often folded diagonally to increase stiffness and reduce noise. Noise is vibration. A straight ribbon would be floppy, a formed ribbon will be stiffer.

Awesome breakdown, thank you. Here in southern Appalachia we heat exchange with our stills the same way, copper tubing with max thermal exchange through the walls of the tube, not the ends. ... . .

Great video. Shows the power of computer simulation ie gut feel is not always right.

Ty for taking the time to so clearly and professionally lay out this presentation. The graphics and production quality hit way above what you'd expect given your subscription count. I know this took a long time e to put together. I learned a lot. I hope your channel grows. Subbed.

Pretty much nailed it. One of the reasons I have a hard time recommending cold plate cooling.

This is amazing analysis. Rivian and Lucid used plate cooling on their EVs. I think that they will have performance issues when performing back to back drag races. Tesla Plaid does not have this issue since they fixed the serpentine ribbon cooling to a parallel ribbon cooling like the Model 3. The optimal design for heat dissipation then would be the tabbed 18650 cell with parallel ribbon cooling based on your analysis. Great job Jordan.

Thanks Jordan! Vinfast of Vietnam is starting to use an innovative battery pack per Sandy Munro.

Something nobody seems to ever mention is the relative simplicity of the manufacturing equipment required to make large cylindrical cells compared to pouch types. The simpler the equipment, the more reliable and the cheaper it is to produce. It's also easier to ramp up the production rate than all of the stop-start motions and complex alignment moves required for pouch cells. I really can't see Tesla changing from a simple to a complex line which much surely take more factory space, even if there are marginal gains in other areas. Elon keeps saying that the product is the factory, and the large cylindrical cell format fits that narrative perfectly.

Learning is so great, thanks for bringing us all along on your journey!

Small correction LEAF batteries aren't actively cooled, just passive heat transfer, 1rst gen Ioniq is example of active air cooled battery

I definitely think that the thicker casing of the structural 4680 cells will help spread the cooling more evenly around the entire circumference of each cell, helping to negate the increased ratio of diameter to length found in the 4680 (as well as the structural benefits).

I would also have thought Tesla would switch to "bottom/top cooling" since it's far less complex to assemble. The only thing I had my doubts about was the height, because the cells are now even longer, which would make the floor structure difficult for a sedan. Nice work!

Great video, Jordan! Thoroughly enjoyed learning about battery tech with you as always!

The way that the current collector jumps from the outer edge to the core, skipping the middle layers, is exactly what you would want to reduce the temp increase in the center. If you contacted all the layers then the outer layers would "use up" the cooling potential, make it less cool where it hits the center hotspot. There may be an analogous electrical advantage if the electrical resistance to the center is also higher, though not obvious why that would be so in the tabless design.

I built a LFP battery for a RV that gets used daily - 6yrs old now - new cells were Bottom balanced @2.75 volt - cell balancer units were not reliable at the time so did not install one - battery discharge to 40% daily - solar charge - I check battery cell balance every few weeks - cells hover around 4mv difference - Amazingly Good

Dear Jordan, a small correction: it is not important that the individual cells have almost identical capacity, but that the capacity of sets of parallel cells sums up almost equally. Keep up your excellent work! I did not miss a single episode almost from the beginning.

I LOOOOOOVE that kind of content.

With base plate cooling, the cans are attached to the cooling plate rather than a structural plate. I imagine the latter yields better structural strength/rigidity.

Thanks a lot for the video and for sharing the reference. You can still use the explanation showed here in order to demonstrate that the prismatic can be as good as a cylindrical 🙂. The conductivity alone is pointless, and using the thermal resistance is more realistic for choosing the best cooling direction ( Thickness/(Conductivity*Cooling_surface). In the case of the cylindrical cell, the radical conductivity is quite poor compared to the height direction. But the radial direction has higher surface. There is a possibility to make the top/bottom cooling better but due to cell integration and important contact resistant in the height (gasket, gaps, electrical insulator) , the height is less interesting. Finally in the case of the LFP from CATL , you can apply the same reasonning and due to the use of the LPF you can have a higher Tmax overall and you do not need higher cooling surface. The sum of improvement of TESLA is driven by cost per performance and tooling is one of them. My guess is that there is less ivestment by staying in cylindrical instead of switching to another form factor. The increase of cell size has been done by CATL and BYD already in 2018 and they have also updated tabs and the number of JR inside the cell in order to cope with the thermal drawbacks

Class is in session! Let's go Jordan!

Wow. Have learned so much watching your videos on your channel. What a humble/open-minded teacher! I do have a question about the thermals on this 4860 cell. And even the guess that the 4860 cylindrical may be better that that flat rectangular pack (prismatic) for an LFP chemistry package. You say (at 06:57) that "more surface area per unit of volume, which would improve thermal management" (comparing the CATL prismatic rectangular) Wouldn't a thin rectangular pack as you display have far greater surface area for a desired VOLUME of battery material? To contain a volume with an outer boundary with the absolute minimum surface area, the sphere is the choice. Next would be the cylinder. Next would be a perfect cube, and rectangular could provide near infinite surface area (really thin). And beyond surface area, it is unavoidable that the center of the cylindrical cell will be much hotter than the outside than the battery material near the outer radius. If thermal homogeneity is highly desired as you detailed in the video, why would you want to increase the radius of the cylinder, creating even more temperature differential? In fact, would not a thin rectangular pack (as shown from CATL) be a perfect match for a plate cooler with far better thermal bond between package and plate, and minimum thickness of the package? **************************************************************** Different topic.... In general, I am very confused about this 4680 cell on the thermals. Here is my thinking. Where do I get this wrong? 1) A larger capacity cell will require less number of cells in the final battery pack of a given desired capacity. 2) As cell voltage is same between 2170 and 4860 battery packs, the same number of cells are needed for a series run to 350 volts. Therefore the percent increase in capacity of the bigger cell will necessarily require the same percent reduction of parallel connections of cells. 3) Less parallel runs means that each series run of cells needs to handle more current (for net same pack current in/out). Therefore the percent increase of energy capacity from the smaller cell (2170) to larger cell (4680), WILL ALSO REQUIRE THE SAME PERCENT INCREASE IN CURRENT LOAD CAPABILITY. 4) Assuming volumetric energy densities are maintained between 2170 and 4860 (same chemistry).... .....for the same net pack current load (between a 2170 cell system and a 4860 cell system), that 4860 battery CELL will have to push 4.45x (volumetric ratio 4860 to 2170) the current of the 2170 CELL. And the losses will be 4.45x the 2170 CELL. That is the heat load to be removed by the cooling system. So far, so good. 5) BUT, in a cylindrical system, for a given length of battery, the ratio of outer surface area to volume is not a constant. As the radius of the battery increases, the volume grows by the square of radius, and the surface area grows only proportional to radius. In other words, the new 4680 cell has to dissipate 4.45X the losses of the 2170 cell. Simple conductance heat transfer: you better have 4.45x surface area as the 2170 cell to dissipate that higher loss load. But you don't. You have only half of what you should need due to cylindrical surface area/volume ratio that gets lower as radius grows. That has to be a major challenge. And now the area of the center of the battery that is generating heat has to travel 2.3x the distance to get to the cooling medium on the outer case. And I would guess that temperature differentials increase 2.3x, further raising the center area temperature. ********************************************************** I am really confused by this direction. No doubt, less batteries good from a battery production and from a pack construction standpoint. But growing radially versus longitudinally makes absolutely no sense to me.. HELP! Must be doing something wrong on my end.

Surely this heat management advantage is going to play into improved charging characteristics. Either for one of charging or constant cycling such as the Tesla-Semi is likely to experience.

Excellent analysis. What you did not say is that one end of the battery is great for cooling, but at the other end there is the electrical connections for both positive and negative. Perhaps also some thin wires which monitor the performance of each cell. So, it will both add complexity and be of less value thermally, perhaps not worth the effort, to extract heat from both ends of the battery in the end cooling scenario.

Also, cooling between cells maximizes cooling while minimizing cooling lanes required. having coolant flow on the bottom or top of the pack would only cool the cells on one side, and need to be insulated on the other side. (you don`t wanna cool/heat the structure around the cells) if the cooling channels are not the full height of the pack, they probably won`t hurt rigidity, because the lever is the highest on the top and bottom of the cells anyway. think of hollow structures or half-timbered structures.

I always assumed that with the tabless 4680s, plate cooling would be the way to go. I was wrong too. I think one phenomenon to emphasize is "thermal contact resistance", especially in a possible next episode about this topic. This is the thermal resistance from very thin layers of a fluid or gas between adjacent solids. For example between the overlapping tabs in the end caps of the cell. This type of resistance can be orders of magnitude larger than the thermal resistance of the adjacent solids. This resistance can really "choke" the overall thermal conductivity in the cell axial direction.

I would have also gone for a top/bottom cooling. In a uni e-motorcycle competition i designed the battery pack cooling i such a way, not appreciating the full jellyroll + can approach since the infor the papers showed the later years was one approaching the jellyroll alone, with very poor radial conductivity. Also, we weren't focused on durability buy max T in 5-10 battery cycles. For the new prismatic cells bottom heat sink utilization was a no brainer

I thought I heard ( but I am not sure from where) that with generation 2 batteries and the new 3 stages combined rolling equipment they were going to omit the copper current collector and laser weld the copper foil turnovers directly to the can base.

I wonder if there's a way to use the natural void in the center of the cell for liquid cooling? This would allow the cells to be closer together creating a higher with volumetric energy density pack. Maybe you could even have a passive mechanical thermostat in the center of each cell, allowing each cell's temperature to be controlled as an individual.

Thanks again for the great content :) Love your deep dives :)

The model 3 LFP pack is already using large format prismatic cells, Munro showed one in one of it videos of him visiting a vendor. I couldn't find any other sources to confirm it, nor did they go into any significant detail like how it was cooled iirc.

I am probably a bit late to mention that if doing base cooling, and there is a thermal runaway event, the expansion has to go down through the base, destroying the cooling at a time when it is needed most

🤗THANKS JORDAN AND YOUR PATRONS 👍 GREAT EXPLANATIONS ,EASILY UNDERSTOOD BY LAYPEOPLE…🤔 It would be great to buy you lunch someday,since I am in N.E. OHIO…IF YOU COULD SPARE THE TIME 🤗💚💚💚

Second time watching through. Takes awhile to get all of it and I'm sure I'm not there yet. BTW, could we please have some color choices for the hats. Please.

Nice job! I think you may have overestimated the thermal conductivity along a thin sheet of electrode and underestimated the thermal conductivity through a thin plastic sheet. It would be interesting to see if the people doin the modelling published numbers for that.

Great info. Thanks Jordan.

Cu and AL plates on top and bottom of 4680 are intricate in order to bend each leaf in order to laser weld them to the tab spiral.

You get passive baseplate cooling as this up against the pack exterior. The only way to side cool is ribbon.

Imo, this all ties in with the "odd" charging curve displayed by the "Korean cousins". They seem to have a "front half,/ rear half" temperature differential which they can't control.

I believe the Tesla battery pack design consist of a group of cells connected in parallel and then these groups are connected in series. Within a paralleled group of cells the BMS doesn’t know anything about the individual cell, just about the groups. I’m not certain if this affects any of your conclusions in the video, though. 3:30

Do you know of any studies showing which type of batteries are lighting up and what the conditions were? We've seen plenty of fires in line but nothing about which ones, if it was design problems or external. Thanks for your work.

Professional! Clear! and Well Done!

Tesla's battery cells don't really need maximum thermal performance typically. Cells don't get that hot normally unless in extreme conditions like at the track perhaps. Also, uniformity is good when cooling or heating, you don't want the bottom of the cell to be different than the top half, so ribbon cooling cools the entire jacket which then cools the entire cell, making it uniform temperature. Good thermal management is needed for long term performance of the cells, but having maximum thermal conductivity is not even really necessary.

Great overview! I hope someone can further clarify the "peak voltage power delivery" aspect of the 4680 vs 2170. Currently a Model 3 loses massive amounts of horsepower as battery SOC gets lower. I assume it's due to rapid voltage sag. Range may be unaffected but a Performance Model 3 with 30% SOC drives nothing like one with 85%. Will the 4680, by it's design, be more able to perform similar to the Tesla Plaid, where the car performs steadily until a much lower SOC is reached?

So now Im thinking that the extreme thickness of the material for the 4680 cans is not just for structural rigidity, but also to increase the thermal conductivity of the cans themselves.

It's amazing how many problems around us are related to thermodynamics. The ability to solve them require you to understand the three thermodynamic laws, and in today's world, the ability to computer model your problem using differential equations Hey, It's all about the Thermodynamics! Nice to hear that Tesla is focused on making their batteries last. Still have other components that need the same life cycle (BMS, welds, wiring, moisture intrusion prevention, etc)

I remember when Rivian engineers were making funny remarks about Tesla's ribbon cooling.

Sometimes the initial choice for a particular design maybe the best over time, even for a company which keeps refining its design. The side cooling ribbon design is still bringing the best result for Tesla. However Lucid is doing its cooling through the bottom end of it cells which does not make too much sense in terms of surface contact area!

Thank you for battery tech deep dive

Jordan. I have a hypothesis regarding the Panasonic "5 tab(?)" 4680. If there's an issue "air folding" the tabs along the length of the Tesla cell(?) How about if the Panasonic cell has a "raw conductive edge" along one side, of the Anode/ Cathode strip, without tabs, except for the last 140mm (the outermost winding) which would have fewer, but wider, longer (about 17mm?) tabs to fold across the bare edges to the centre, like wheel spokes. These would contact the bare edge of the inner windings. . Then, weld a sprung endcap, similar to the Tesla cell, to provide contact by pressure when the steel cap is positioned. . Most contact would be by pressure from the endcap onto the wound bare foil edges rather than the folded tabs, which would simply provide a welding location during assembly. . This would seem to provide the same advantages and characteristics, without the complication of cutting and folding fine tabs? (Hope this makes sense) . Example. Roll a strip of tin foil around a pencil 20+ times. Wind tape around the outside to secure. Slide the roll off the pencil. You still have what is essentially a metal contact, without tabs. If you press a disc on top (a coin?) The pressure maintains contact.

Yes clearly the correct approach in this case though it's not perhaps the case for other form factors.

Great video Jordan! Does this assume the same coolant inlet temperature?

This is one of my favorite channels

If it can conduct electricity, it can conduct heat. The current collectors at the top are wicking away heat then conducting over to side can. Dual purpose for sure. The tabless design is also drawing heat out from the center for same reason ohmic resistance is lowered. Did not surprise me that side cooling works.

It would seem that the pack encapsulation by the pink material would contribute to heat removal if it is thermally loaded.

Prismatic for LMFP and LFP. It seems that most companies, like CATL's CTP 3.0 Qilian, use prismatic because they can integrate liquid cooling and a thermal heating pad into the pack. It will be much more plug and play with no need for OEM's to engineer complicated thermal management systems, they will just be built in to the battery pack. We should also start to see lithium doped hydroxyapatite added to the separators. Think of a bone material in which the lithium electrolyte flows through. Should be great thermally.and safety wise.

My guess before watching(although I do actually remember them planning on plate cooling) - they found out that the tabless cells produce less heat so they could still use ribbons

The video I've been waiting for!

I wonder where the Munro and Associates would like to see the breakdown of your battery ideas

Bigger batteries with better cooling mean that you can potentially charge every cell on its own, and potentially less cells can be bunched into a group/pack, the ideal being each cell a pack.

Here’s where Tesla’s “Fail Fast” philosophy makes a difference. Tesla’s engineers very likely just came up with several different ways to cool the cells, including ribbon cooling, and just measured the temp difference under load. They didn’t write a paper, they just found out what worked best via direct experimentation. It is often the case that you can make something and tear it apart and remake a new design of it five times in the amount of time you could verify something theoretically. In other words, building something and live testing it in the real world is often faster than theoretically modeling something before building it. Also, building things live gives opportunity to stumble upon new findings and knowledge that might well have been missed by modeling something to get a result before building it. I worry a lot about todays engineers getting too far away from a hands on understanding of materials. It is better to have an idea and build it and test in the real world and refine and rebuild than it is to computer model something to death before ever building it. Sure there are exceptions such as when you need to know if something is possible at all, but hands on is the quickest and best teacher.

You made some comparisons to some Chinese battery packs at the end. Could you do a video on the engineering of those packs and how they compare to Tesla and other domestic auto-makers?

Great presentation as normal

I believe your original assumption concerning end verses side cooling to be correct when it comes to end/tab cooling, though side cooling could potentially be superior if implemented correctly. The problem as I see it is that Tesla’s ribbon cooling solution cannot achieve equal cooling to all the cells, meaning the cells at the intake side will experience lower coolant temperatures compared to those cells at the outtake side of the pack. The other problem is that the ribbon as you have explained is only contacting at best 20% of the cells side area, a further problem is how to guarantee adequate thermal contact between the cooling ribbon and the cell side cylinder wall. No matter what, you have given me something to think further about.

by your logic, shorter fatter cells could cool as well or better than taller cells. But Tesla tends to do full systems analysis and not incremental analysis. Thanks for all the analysis you do.

also, the bottom of the cell has a noticeable airgap between the active materials and the casing, thus really not effective cooling area Vs side. Cooling from the top gets challenging as that's where the electrical connections are made for positive and negative welds.

Question: the cells are encased in some tough polymer as the Munro tear down showed. I get that the polymer has limited cooling capacity, unless Tesla designed that material to absorb some heat. Once warmed maybe any potential cooling bennies are negligible?

Another great video, thank you.

great video as always. could you explain how does the cooling system works in tesla's LFP models? thanks

Greta video but I would like to point out that plate cooling also utilizes the Can of the cell to cool the sides of the cell as well, Plate cooling allows the copper and aluminum conductors a less Thermally restricted path for heat transfer whereas in just side cooling 20 percent area the heat has to travel through multi-layers within the roll of the cell to cool. This is still effective but the difference is seen when the cells are stressed thermally in high-current modes of operation. This is why Ribbon cooling is not as effective in race conditions or long-duration high current draw situations. Of course variables such as coolant temp can factor into this but as a researcher who has experimented directly with cylindrical cells , Plate cooling a cell that is designed for it is more effective at heat transfer. I am curious as to why you did not use the Lucid module design ( a plate-cooled cylindrical cell ) in any of your comparisons as that would have been a more comparable difference between the 2 types of cooling methods.

🤗👍GOOD AFTERNOON JORDAN 👋🤗💚💚💚

Great cooling video: Question: Why have they not run the cooling in a more serpentine fashion to create a greater surface area for cooling?? ~~~~~~~~.. One cooling arm could cool two row of batteries with more than 50% of the can surface area in contact. I realize that it would add a small amount of weight, but this seems negligible compared to the battery life savings with improved thermal management.😀 Thanks

Excellent rundown.

Maybe this is a dumb question, but why packing thausen of cylindrical batteries vertically when you can stretch the battery to 2 meters long pipe like design, and packaging in a horizontal styles, like a floor made of pipes?

I wonder if the cooling becomes less effective towards the rear of the Pack as the heat is absorbed from each cell?

Not sure why they stopped at 46. They could have gone for 8080 with a hollow core instead. This would give them cooling lines through the whole core and 80% of the circumference. It would also make it trivial to connect those in series, as they line up that way automatically when threaded onto the central cooling pipe.

Can you do an analysis on StoreDot and its battery chemistry? Can you confirm(debunk) the validity & effectiveness of Silicon based anode NMC cathode? Is it a sham or is solid state truly be the future of battery innovation?

You mention a potential video about can wall thickness affect on heat and wicking it away but I was wondering about how can wall thickness affects charging speed. My understanding is that cold cells charge slower and so there's a need to heat the batteries up or keep them warm - especially in cold weather. So presumably a thicker walled can would make it harder to get necessary heat into the pack/cells because the thicker walls would wick heat away from the jellyroll.

Ribbon cooling is a little bit cheaper to implement in manufacturing. I'm pretty sure that's the only reason because the electrode itself is actually a long flat ribbon that's been coiled up which means that cooling the side is not actually cooling the side, you're cooling the ends essentially. The heat actually can travel faster along the width of the ribbon up to the top of the cylinder and then out to the sides because of the larger thermal mass then it does around the coil a bunch of times to the outside. Cooling the outside of the cylinder is easier than cooling the top and the bottom together and cooling the side cools it roughly equally. It's pretty good, it's pretty cheap, it's pretty easy to do, pretty reliable, and overall just a good balance of lots of factors. It's not really the best in any regard but without spending ridiculous money this is kind of the best compromise for the money