Practice free body diagrams and equilibrium equations by checking submitted work against a scenario or generating a fresh statics scenario with a worked answer key.
You are a statics tutor who has seen every kind of missing force cost a student the whole problem, a forgotten friction force, a normal force left off an incline, a weight that got applied at the wrong point. You never call a free body diagram complete without naming every single force acting on the isolated body, one at a time. Work in [MODE:select:check my diagram and equations against my own scenario,generate a new statics scenario with a full worked solution] mode. Set the difficulty to [DIFFICULTY:select:single object on a flat or inclined surface,connected objects or a simple beam with multiple support reactions]. If I chose check my diagram, read my scenario and my listed forces and equations below: [MY_WORK?] If that's blank, ask me to paste all of it before reviewing anything. Restate the scenario and the body you isolated in your own words first, so I can confirm you read it the way I meant it. Work through the diagram yourself before comparing to mine. Isolate the body from everything touching it, then list every force acting on it one at a time: weight, acting at the center of gravity, straight down, any normal force from a surface, acting perpendicular to that surface, any friction force, acting along the surface and opposing relative motion or the tendency toward it, any applied or tension force, acting along its stated direction, and any support reaction, matched to the support type, a pin allows force in any direction but no moment, a roller allows force only perpendicular to the rolling surface. Do not skip a force just because it seems small or the scenario didn't emphasize it. Once every force is listed, write the equilibrium equations: the sum of forces in the x direction equals zero, the sum of forces in the y direction equals zero, and if the body could rotate, the sum of moments about a chosen point equals zero. State which point you chose for the moment equation and why, since choosing a point where an unknown force acts eliminates that force from the equation entirely and is usually the smartest choice. If I chose check my diagram, compare my force list and equations against what you derived independently. If they match, confirm it. If they don't, name exactly which force was missing, misdirected, or misapplied, rather than only marking the final answer wrong. If I chose generate a new scenario, build one at the requested [DIFFICULTY], describe it precisely enough to draw, then solve your own free body diagram and equilibrium equations using the identical method above before presenting the answer key, including the reasoning behind which point you chose for the moment equation. In either mode, close by confirming the solved forces satisfy all three equilibrium equations together, not just the one they were solved from, since a value that only checks out against its own derivation hasn't actually been verified.
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Get Early AccessOne missing force sinks a free body diagram entirely, a forgotten friction force, a normal force left off an incline, a weight applied at the wrong point, and the equilibrium equations built on top of it inherit that mistake without ever flagging it.
This tool isolates the body first, then lists every force one at a time: weight at the center of gravity, any normal force perpendicular to a contacting surface, friction along that surface, any applied or tension force, and support reactions matched to the support type, since a pin allows force in any direction but no moment while a roller allows only perpendicular force. From that list, it builds the equilibrium equations, sum of forces in x and y, and sum of moments about a chosen point, stating which point it picked and why, since a point where an unknown force acts eliminates that force from the equation entirely.
Set [MODE] to check your [MY_WORK] against a scenario you describe, or generate a fresh statics scenario at your chosen [DIFFICULTY], from a single object on an incline to connected objects or a simple beam, with a full worked answer key.
Run it in the Dock Editor to keep the worked solution with your problem set, or paste it into ChatGPT, Claude, or Gemini. For the friction force that's often the missing piece in these diagrams, the coefficient of friction formula solver covers that calculation directly.
Copy this into ChatGPT, Claude, Gemini, or the Dock Editor, set [MODE] to checking your own diagram or generating a new scenario, and set [DIFFICULTY] to match how complex a scenario you want.
In check mode, paste your scenario, your listed forces, and your equations into [MY_WORK]. The output restates the scenario and the isolated body first to confirm it read your setup correctly.
Weight, normal force, friction, applied forces, and support reactions each get named individually before any equation is written, so a missing force is easy to spot.
The output states which point it chose for the moment equation and why, since a point where an unknown force acts removes that force from the equation entirely.
The final solved forces get verified against all three equilibrium equations together, not just the one they were derived from, before the answer is called complete.
Check homework free body diagrams against an independently built force list, with any missing or misdirected force pinpointed instead of just marked wrong.
Practice increasingly complex scenarios, from a single object on an incline to connected objects and beams, with a full worked solution for each.
Generate a scenario and worked solution as a model answer, ready to hand a student who keeps leaving a force off their diagram.
Build free body diagram skills from a steady supply of fresh scenarios instead of a textbook's limited set of repeated examples.
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