Does an optimal driver descent angle exist? We put 47 drivers on a robot to find out

ASFN Admin

Administrator
Administrator
Moderator
Supporting Member
Joined
May 8, 2002
Posts
1,200,024
Reaction score
59
During a recent testing session with the swing robot, we observed two drivers produce ball speeds that differed by two-tenths of a mile per hour. On a launch monitor, that's essentially the same ball speed.

But here's where things got interesting: One of them carried the ball 20.5 yards farther than the other.

A gap that size between two drivers delivered at an identical 95 mph is not a ball speed story. The number that separates those two heads, and that separates much of the field in this particular test, is descent angle, which is the trajectory the ball is falling on when it comes back down to earth.

Descent angle has been a key cog in the fitting process for years, and is analyzed after the ball reaches its apex. Figure out the optimal descent angle for your driver, and you should optimize carry.

The standard line is that a well-fit driver lands the ball somewhere in the mid-to-high 30s—steep enough to maximize carry without ballooning. Fitters treat the number as a checkpoint, and plenty of golfers have walked out of a fitting bay convinced their driver is dialed because the screen showed an optimal descent window.

But what exactly is optimal? During a recent trip to Carlsbad, Calif., TaylorMade master fitter Duane Anderson told me it was 35 degrees with a driver. Titleist has conducted studies that confirm it's between 35-40 degrees, but not below 35.

Curious if a magic descent angle number exists, we went searching for the optimal window. For the latest round of Golf Digest's robotic testing series, we put 47 10-10.5-degree drivers spanning the last three product cycles from nine manufacturers on the swing robot at 95 mph. Six shots were struck from nine impact locations, leading to 2,538 shots in total. All shots were delivered with a neutral attack angle, square face/path and the same Titleist ball throughout.

With every head measured under identical conditions, we were hoping the testing data could help answer a question a fitting bay can't: Across the whole market, does landing in the optimal descent range actually correlate with the longest carries?

The short answer is that the window everyone talks about doesn't behave like a window. It actually behaves like a floor, and that floor just so happens to include a 30-degree cliff.

Numbers at a glance 47 drivers, ranked by carry at 95 mph Average carry across all 54 robot shots per head, with average ball speed in miles per hour and average descent angle in degrees. Descent angles below 30 degrees appear in red. The field spans 22.7 yards of carry on just 4.7 miles per hour of ball speed. RANK HEAD AVG CARRY, YARDS BALL SPEED DESCENT 54 shots per head degrees 1 Ping G440 LST 223.6 138.0 34.3 2 Callaway Elyte Triple Diamond 221.4 138.4 32.6 3 Ping G440 Max 221.4 136.7 35.0 4 Callaway Elyte 220.9 136.8 33.6 5 Titleist GT4 220.7 137.5 32.1 6 Cobra Dark Speed Adapt Max-K 220.3 138.3 30.4 7 Cobra Dark Speed Adapt X 220.3 136.8 35.9 8 Callaway Elyte X 219.8 137.2 35.8 9 Titleist GT3 219.8 136.9 32.0 10 TaylorMade Qi35 Standard 219.4 138.7 34.0 11 Cobra Dark Speed X 219.1 137.2 31.5 12 TaylorMade Qi35 Max 219.0 138.0 37.1 13 TaylorMade Qi35 LS 218.7 137.9 37.1 14 Cobra Dark Speed Adapt LS 218.5 136.4 31.2 15 Callaway Ai Smoke Triple Diamond 218.2 136.6 36.8 16 Titleist GT2 218.2 137.1 32.5 17 Srixon Zxi 217.8 137.3 36.6 18 Srixon Zxi LS 217.2 136.9 32.8 19 Ping G440 K 216.8 136.5 33.7 20 Srixon Zxi Max 216.6 137.4 33.7 21 Cobra Dark Speed Adapt Max D 216.2 134.2 37.0 22 Cobra OPTM X 216.2 135.5 34.1 23 Callaway Quantum Triple Diamond 216.1 136.1 29.9 24 Cobra Dark Speed LS 216.1 136.6 37.2 25 Ping G430 Max 10K 216.1 135.1 35.6 26 PXG Lightning Tour Mid 215.8 136.5 32.2 27 Callaway Quantum 215.7 135.7 33.3 28 TaylorMade Qi10 Standard 215.4 137.6 33.9 29 PXG Lightning Tour Max 10K+ 215.1 135.6 33.3 30 Ping G440 Max SFT 215.1 135.2 42.1 31 PXG Lightning Tour 215.0 135.5 30.5 32 Callaway Quantum Max D 214.9 134.8 36.1 33 Cobra OPTM LS 214.8 137.6 29.8 34 TaylorMade Qi10 LS 214.8 138.5 29.7 35 Callaway Ai Smoke Max 214.6 134.1 36.1 36 Callaway Quantum Triple Diamond M… 214.3 135.2 32.1 37 TaylorMade Qi10 Max 213.9 137.8 34.4 38 TaylorMade Qi4D Standard 213.1 137.4 29.3 39 Cobra Dark Speed Max 213.0 135.1 39.4 40 Wilson Staff DYNAPWR Max Plus 212.7 137.1 28.1 41 Callaway Ai Smoke Max D 212.6 134.0 42.2 42 Callaway Elyte Triple Diamond Max 212.6 134.4 36.5 43 TaylorMade Qi4D Max 211.5 135.6 33.5 44 TaylorMade Qi4D LS 210.7 135.0 32.0 45 Cobra OPTM Max K 209.9 137.9 27.2 46 Mizuno JPX One 209.5 137.3 30.5 47 Mizuno JPX One Select 200.9 136.5 24.6 195 205 215 225
The field covers a 22.7-yard spread in average carry, from Mizuno's JPX One Select at 200.9 yards to Ping's G440 LST at 223.6. That's a meaningful gap for two drivers swung at an identical 95 mph. The first instinct is to assume the fast heads are producing more carry. But they aren't, at least not by much.

The entire field sits inside a 4.7 mph ball speed range, from 134.0 to 138.7. At roughly 1.1 yards of carry per mph, ball speed differences can account for about five yards of that 22.7-yard spread. Run the correlation across all 47 heads and ball speed explains 12 percent of the carry variance.

The number golfers fixate on hardest in a hitting bay turns out to be nearly useless for separating drivers at the same swing speed, because at the same swing speed, modern drivers are all fast. The other 18 yards of the spread come from what the ball does after it leaves the face.

The G440 LST makes the point from the top of the field. Its ball speed of 138.0 is quick but not the fastest in the test. Its carry lead comes from pairing that speed with a flight that gives nothing back: 34.3 degrees of descent, and six full yards of carry beyond what its ball speed alone predicts, the largest overperformance of any head we tested. Its stablemate, the G440 Max, is the longer half of the pair that opened this story, and runs nearly the same playbook: 136.7 mph of mid-pack ball speed converted into 221.4 yards of carry by way of a 35-degree landing.

The cliff The cliff at 30 degrees Each dot is one driver head. The vertical axis shows carry relative to what each head's own ball speed predicts: zero means the head carries exactly what its speed suggests, positive means it beats its speed, negative means it leaks. Below 30 degrees of descent, every head in the test gives carry back. At 30 and steeper, the relationship goes flat. Descent below 30 degrees (7 heads)Descent at 30 degrees or steeper (40 heads) -15 -10 -5 0 +5 25 30 35 40 THE CLIFF below 30 degrees: 5.1 yards lost on average THE PLATEAU 30 degrees and steeper: descent and carry overperformance no longer correlate Mizuno JPX One Select Cobra OPTM Max K Wilson DYNAPWR Max Plus Ping G440 LST Callaway Elyte TaylorMade Qi10 Max AVERAGE DESCENT ANGLE, DEGREES CARRY VS BALL-SPEED EXPECTATION, YARDS Source: Golf Laboratories robotic testing for Golf Digest, 95 mph club speed, 47 driver heads, 54 shots per head. Carry expectation derived from the field-wide relationship between ball speed and carry, roughly 1.1 yards per mile per hour. Within the group at 30 degrees or steeper, the correlation between descent angle and carry overperformance is 0.03.
Here's where the orthodoxy gets interesting. Strip ball speed out of the equation entirely, so every head is measured against the carry its own speed should produce, and then line the field up by descent angle.

Seven heads land the ball shallower than 30 degrees. As a group, they carry 5.1 fewer yards than their ball speed predicts. The extreme case is the JPX One Select, the shorter half of the driver mentioned at the outset. Its ball speed of 136.5 mph is mid-pack, closer to the fastest driver in the test than to the slowest.

But it lands the ball at 24.6 degrees, the shallowest flight in the field by a wide margin, and it carries 15.2 yards less than that ball speed should produce. The JPX One Select isn't doing all the work in the group average, either: remove it and the remaining six still give up 3.4 yards.

Cobra's OPTM Max K, landing at 27.2 degrees, loses 7.6 yards despite producing a top-seven ball speed in the field. Wilson's Staff Dynapwr Max Plus gives back 3.9. Below 30 degrees, the penalty is real, it's consistent, and it hurts heads that have no obvious problem anywhere else on the launch monitor.

Then the penalty disappears. The 40 heads landing at 30 degrees or steeper carry, on average, are about a yard more than their ball speed predicts. And within that group, the correlation between descent angle and carry overperformance is 0.03, which is within the noise. A head landing at 32 degrees is no worse off than a head landing at 38. According to the robot data, once a driver clears the floor, a steeper descent doesn't offer a power-up.

That's the cliff. We expected the data to draw a bullseye somewhere in the mid-30s, with carry falling away gently on both sides. Instead it drew a flat plateau with a sheer descent at one end.

The longest heads in the test cluster in a band, with the top 10 carries landing between 30.4 and 35.9 degrees, with a median of 33.8 degrees. But the clustering describes where good drivers happen to live; it's not a gradient a fitter can climb. The difference between the 33-to-37 band and its neighbors on either side is about a yard, which is inside the noise.

The counterexamples The window doesn't pick the winners Three heads land shallower than the textbook mid-30s target and beat their ball speed anyway, on launch in the 10-to-11-degree range and spin in the mid-2,000s. One head lands inside any version of the window and leaks carry, because a launch under 10 degrees paired with spin over 3,000 rpm costs yards long before the ball starts falling. Below the textbook target, beating their speed Callaway Elyte +4.6 yards vs ball-speed expectationDESCENT33.6 degreesLAUNCH11.2 degreesSPIN2,468 rpmBALL SPEED136.8 mph Titleist GT4 +3.7 yards vs ball-speed expectationDESCENT32.1 degreesLAUNCH10.7 degreesSPIN2,498 rpmBALL SPEED137.5 mph Titleist GT3 +3.4 yards vs ball-speed expectationDESCENT32.0 degreesLAUNCH10.9 degreesSPIN2,402 rpmBALL SPEED136.9 mph Inside the window, leaking carry TaylorMade Qi10 Max -3.4 yards vs ball-speed expectationDESCENT34.4 degreesLAUNCH9.9 degreesSPIN3,182 rpmBALL SPEED137.8 mph
During testing, two heads made the case against the bullseye better than any correlation could.

Callaway's Elyte lands at 33.6 degrees, just below the range orthodoxy says it should be. It also carries 4.6 yards beyond what its ball speed predicts—one of the best conversion numbers in the test—on a launch of 11.2 degrees and spin of 2,468 rpm. Titleist's GT3 and GT4 tell the same story a degree lower, landing at 32 and beating their speed by more than three yards apiece.

Now look at the TaylorMade Qi10 Max. It lands at 34.4 degrees, inside any version of the window you want to draw, and it carries 3.4 yards less than its ball speed predicts. The problem never touches the descent column. The Qi10 Max spins at 3,182 rpm, fourth-highest in the field, and it pairs that spin with a launch of just 9.9 degrees. That combination is losing carry on the way up, long before the ball starts coming down. The landing angle looks textbook because high spin produces a steep descent. The screen says it's optimized, but the carry says otherwise.

The heads that beat their ball speed in this test share a launch in the 10-to-11-degree range and spin in the mid-2,000s, and across the field, launch angle correlates with carry overperformance at 0.55, meaningfully stronger than what we saw from descent by itself.

If you're able to get the launch-spin combination right, then the descent number takes care of itself.

What the robot data tells us The field: ball speed against descent angle All 47 driver heads by average ball speed and average descent angle across 54 robot shots. Dot color shows design tier; outline ring shows manufacturer. The shaded zone marks descent angles below 30 degrees, where the test's carry penalty concentrated. No zone above 30 is shaded because the data showed no carry advantage anywhere above it. DOT FILL, DESIGN TIER StandardLow-spinForgiveness10KDraw-bias OUTLINE RING, BRAND TaylorMadeCallawayCobraPingPXGMizunoWilsonSrixonTitleist BELOW 30 DEGREES 24 26 28 30 32 34 36 38 40 42 134 135 136 137 138 139 Ai Smoke Max D G440 Max SFT Dark Speed Max Dark Speed LS Qi35 Max Qi35 LS Dark Speed Adapt Max D Ai Smoke Triple Diamond Zxi Elyte Triple Diamond Max Ai Smoke Max Quantum Max D Dark Speed Adapt X Elyte X G430 Max 10K G440 Max Qi10 Max G440 LST OPTM X Qi35 Standard Qi10 Standard G440 K Zxi Max Elyte Qi4D Max Quantum Lightning Tour Max 10K+ Zxi LS Elyte Triple Diamond GT2 Lightning Tour Mid Quantum Triple Diamond Max GT4 GT3 Qi4D LS Dark Speed X Dark Speed Adapt LS JPX One Lightning Tour Dark Speed Adapt Max-K Quantum Triple Diamond OPTM LS Qi10 LS Qi4D Standard Staff DYNAPWR Max Plus OPTM Max K JPX One Select AVG BALL SPEED, 54 SHOTS, MPH AVG DESCENT ANGLE, 54 SHOTS, DEGREES
What we learned is that there's a real descent angle cliff, and a player whose driver lands the ball below 30 degrees at 95 mph is losing carry, to the tune of three to five yards on average, and sometimes more in the worst cases.

Just don't worry about trying to hit a specific descent number in the search for more carry distance. Above 30 degrees, the data goes flat, and the difference between landing at 33 and landing at 38 is basically a rounding error.

The two numbers worth more attention are the ones doing the actual work. Launch angle separates the overperformers from the field more cleanly than descent does, and spin is what quietly ruined the one-in-the-window head that had the potential to be long.

A good rule of thumb: Check descent once, the way you'd check your tire pressure. If it clears 30 degrees on the descent, stop looking at it, because the yards you're missing are more than likely upstream.

Continue reading...
 

Members online

Forum statistics

Threads
1,402,515
Posts
6,631,754
Members
6,435
Latest member
taylor_fancav
Top