Range 36? I’d give it to them, unfortunately, Google tells me bless is range 30.
As a long-time DM, this sort of loosey-goosey handling of basic math in D&D is how Flight makes it into 1st level games… ie. “What could go wrong?” is the epitaph for the vast majority of games killed by shenanigans. 😜
Big fight in dire straits, but the group has been having a session that’s helped you flesh it all out more and they’ve been doing deeds in alignment with the cleric’s deity? Shenanigan. Maybe you pass a note to the cleric later to entice them with a quest. Troubling dreams, seek out a shrine, the whole party has the same dream.
Same situation but they earned a bit of a walloping and should have the resources to win or the intellect to run? Shenanigannot.
Dungeons and Dragons is non-euclidian. The length of the hypotenuse is equal to the longer of the two sides. Yes, it’s silly. But that’s RAW
That’s only true for movement. For areas of effect, there are templates for each size for square grids that are roughly shaped like real circles.
No he cannot. I don’t even need to use the theorem to figure that out. He’s already at the maximum range by being 30ft in the air. Unless the party is directly under him, he can’t reach.
I would argue that this explanation still requires a working knowledge of the Pythagoras theorem, even if you don’t employ the formula directly. Specifically the knowledge that the hypotenuse must be longer than either of the sides unless the angle of the non-90 degree sides are 180 and 0, essentially making it a line.
You deducted the hypotenuse must be longer than 30 since they weren’t aiming directly at the ground. Believe it or not, that’s not common sense.
I watched (some) of a History of Mathmatics documentary, and what struck me was how many of the theorems ancient people came up with were just common sense. But they wrote it down: that’s what made it noteable.
There were some theorems/axioms that i had trouble getting my brain to accept, but generally it came down to me not “getting” their number/tally system or simply having no context for why they needed that math in the first place (ie: it wasn’t common sense to me). For example. I’m not an ancient accountant who needs to be able to calculate grain taxes and – at the same time – be able to assure a farmer (who can’t read my number system) that i’m taking the correct amount of his food, so their method of long division using different colored stones seemed needlessly convoluted to me.
Note, too, that there is value in being rigorous about “common sense” assertions.
Some of the most exciting discoveries happen when something everybody assumed they knew turns out to be wrong.
Ope. Hang on.
Normally this is obviously correct, but in this case, we have to consider how tall the characters are. As a DM, I would rule that if any part of the character (their actual person, not including, say, the reach of the sword they’re holding) is within the 30’ circle, or could be if they actively collaborated with the cleric using free actions, then the bless would affect them.
There’s also a few definitions we need to talk about:
- if the cleric (we’ll call them Carl) is 30’ in the air, that is understood to mean that if the spell holding them up there fails, they will fall 30’. By the same token, a character 0’ feet in the air can only fall 0’. We can infer that Carl’s feet (or the bottom part of the PC, at any rate) are 30 feet in air.
- we consider Carl to be in the center of the 5x5 grid square in the plane A formed 30’ above the flat terrain.
- the “allies are 20ft away” part is a bit too fuzzy for this to work (how many allies? which ones? they can’t all occupy the same grid square unless they’re tiny), so we’ll have to make some calls here. Let’s just consider one ally, Alice, who is 20’ away.
- We consider Alice to be in the center of her grid square, in the plane T formed by the flat terrain.
- When we say Alice is “20ft away” from Carl, we mean that a perpendicular line drawn through the cleric intersects with T at the center of a grid square in A–we’ll call this square C(T) and Carl’s square at current altitude C(A), and the center of C(T) is 20’ from the center of Alice’s square A(T). Visualized as a battle grid you would have
C ◻◻◻ A
in plane T, with 3 empty squares separating them. On a physical table, Carl would also probably be standing on a little platform or a d6 to indicate altitude. - “Range: 30ft” 30 feet from what? Definitely not Carl’s god, they’re probably not even in the room. Maybe we mean 30ft from Carl’s 3rd chakra, or maybe it’s just 30ft from any part of Carl’s person. That seems easier, let’s go with that one.
Based on some anthropometric data I found very quickly, the average human woman has a vertical reach of about 77 inches or 6’ 5". That’s naked, and she’s probably wearing boots, let’s add another inch for the soles so 6’ 6".
We can give her a little bit more of an advantage as well; the shortest path between Alice and Carl is a straight line following the radius of the sphere, so she could “lean in” a bit with her arm to get closer. She can’t go a full 45 degrees without falling prone though, so this only adds a little. Without a posable figure and a 3d model of the space in front of me I couldn’t tell you how much she could reasonably add by pointing her body and hand at an angle, so let’s just call it 2 more inches and keep measuring vertically.
We’ll call the apex of her fingertips at 80 inches above T a new plane F, and A(F) is the point where she touches that plane with her fingers.
Now we get to actually apply the Pythagorean theorem. It’s a triangle formed by the points (C(A) -> A(A) = 240") as leg 1 and (A(A) -> A(F) = 280") as leg 2. The hypotenuse, then, is 368 inches.
30ft is 360 inches. Is 80 inches of Alice enough to put a fingertip through any part of a 30ft sphere around Carl’s feet?
No it isn’t. So no +d4 for you Alice, piss off.
In school you think trig is worthless and calculus is the big shit but in the real world it’s the other way around.
I’ll see your Pythagorean Theorem range question and raise you a Feramt’s Last Theorem based magic puzzle/lock/trap (laughs in maths)