I wonder if in a large farm it will be worth running hoses and deploying a frob next to each device vs having an electric robot with a refillable tank walking the rows.
Such a robot is still SF today, so deploying a frob with each seedling would be the only choice at the moment (or continue current irrigation practices). The frobs have to be cheap enough to be consumables.
My gut tells me that the robot will cost less in the long run. It also doesn't seem like a hard problem (yeah, easy to say) since row crops are planted at fixed spacings and detecting that the thing next you is a plant and not a rabbit should not be a difficult task. The combination of GPS mapping (planter knows where it was during planting), known plant & row spacing, and basic visual imaging should simplify the problem.
So why isn't it done today? Probably still cheaper to rely on the weather or center pivot irrigation.
> The combination of GPS mapping (planter knows where it was during planting), known plant & row spacing...
This is not robust. Humans don't use GPS for this purpose (and anyway, the plants are closer than GPS resolution.
Looking and using the local data is the more robust approach. Trying to assume the real world is the same as your model has been the source of countless visual gags since the advent of movies.
Scale, I imagine. Orchards are big. How many robot waterers would you need when you have to spend time at each individual tree (or groups of trees) to water it/them? How far is it to the nearest refill?
Put another way, drip is massively parallel. Robot waterers, not so much.
Let's say the RoboWater(tm) rolls down a row of trees in the orchard, water hose unreeling behind it. At each tree, it dumps the calculated dose of water into a clay pot that is sunken into the ground near the trunk (from which the water slowly soaks into the soil). When the row is done - it reverses direction, reeling the hose back up in the process. Then some side-shuffling, and it's soon rolling down the next row of trees in the orchard, again dumping the calculated dose of water...
> I thought OP was talking about row crops which can't feasibly be irrigated with hoses.
Are we talking about irrigation pivots[1] here? Because those are a known technology.
If we are thinking about robots driving up and down the rows and watering plants from a tank, and then returning to some central location to re-fill their tank that feels like a "carrying water for elephants" situation. I suspect the logistics won't work out. Could try to run some numbers on it of course. Is that how you are thinking about it?
Yeah, and I think you're right. I hadn't even given any thought to the massive weight of the water tank you'd need to do this. I was thinking of it more like a sprayer, which requires a much smaller volume to be useful.
The other issue is the ability to respond to extreme heat quickly enough.
We work with fruit growers in South Eastern Australia where temperatures routinely hit high 30s and even low-mid 40s (°C) a few days each year.
Those growers want to see our soil moisture data readings updated every 15 minutes so they can turn the drippers on very quickly as soon as the soil starts drying out rapidly.
It would just be too slow to rely on robots driving up and down the rows in those conditions.
Row crops can be (and already are) irrigated with hoses. In dry areas of the world, drip tape is buried throughout the entire field because it allows farmers to make more efficient use of the water available to them. It does require the machinery has auto-steer (which is standard practice now anyway), because tearing up the drip tape with a planter is an expensive mistake.
Such a robot is still SF today, so deploying a frob with each seedling would be the only choice at the moment (or continue current irrigation practices). The frobs have to be cheap enough to be consumables.