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Diffstat (limited to 'experiment/frensch_task.py')
| -rw-r--r-- | experiment/frensch_task.py | 430 |
1 files changed, 430 insertions, 0 deletions
diff --git a/experiment/frensch_task.py b/experiment/frensch_task.py new file mode 100644 index 0000000..1949d51 --- /dev/null +++ b/experiment/frensch_task.py @@ -0,0 +1,430 @@ +#!/usr/bin/env python3 +from __future__ import annotations + +import pickle +import random +from collections import namedtuple +from pprint import pprint + +import pandas as pd +from psychopy import core, event, gui, visual + +import frensch_procedures + +DisplayVariable = namedtuple("DisplayVariable", ["name", "values"]) +DisplayProcedure = namedtuple("DisplayProcedure", ["procedure", "solution"]) + +intro_text = """Vielen Dank dass Sie bei unserem Experiment zum menschlichen Lernen teilnehmen! + +In diesem Experiment arbeiten Sie in einem Labor, welches die Wasserqualität analysiert. +Dafür bekommen Sie einige Wasserproben und müssen für jede Probe verschiedene Kennwerte ermitteln. + +Jede Wasserprobe besitzt bereits verschiedene gemessene Werte, wie der Algengehalt, welche für die Berechnungen benutzt werden. + + +(Leertaste zum Fortfahren) +""" + +intro2_text = """Im folgenden müssen sie verschiedene Rechenaufgaben lösen um die Kennwerte zu berechnen. +Verwenden Sie die gewohnten Rechenregeln und geben sie Ihre Lösung bitte immer als zweistellige Zahl ein, und bestätigen mit Enter. +Die Werte der Variablen (z.B. Algen) werden oben am Bildschirm angezeigt. + +Manche Variablen haben mehrere mögliche Werte; "Gifte_2" besagt z.B., dass der zweite Wert der Giftwerte zu verwenden ist. +"_max/_min" besagt, dass der maximale/minimale Wert dieser Variable zu verwenden ist. + +Als letzte Berechnung müssen Sie den Gesamtwert der Wasserqualität aus ihren Ergebnissen berechnen. + +Nach jeder Aufgabe können Sie kurz pausieren. + +Drücken Sie die Leertaste um zu beginnen""" + + +def experiment_shutdown(): + WIN.close() + core.quit() + + +WIN = visual.Window((1920, 1080), fullscr=True, units="pix") +MONITOR_FPS = 60 +TRAIN_TRIALS = 75 +TEST_TRIALS = 50 +# TRAIN_TRIALS = 3 +# TEST_TRIALS = 3 +ORDER_CONDITIONS = ["fixed", "random", "blocked"] +PROCEDURE_KEYS = ["1", "2", "3", "4", "5", "6", "overall"] + +# Cancel experiment anytime with Esc +event.globalKeys.add(key="escape", func=experiment_shutdown, name="shutdown") + + +def generate_variable_display(varx: list[DisplayVariable], x_positions: list[int]): + assert len(varx) == len(x_positions) + + stims = [] + + def gen_value_stims(values, x, y, offset): + for value in values: + y -= offset + value_stim = visual.TextBox2( + WIN, + pos=(x, y), + text=value, + # size=200, + letterHeight=75, + alignment="center", + ) + stims.append(value_stim) + + y = 550 + offset = 100 + + for var, x_pos in zip(varx, x_positions): + stim_var = visual.TextBox2( + WIN, + pos=[x_pos, y], + text=var.name, + # size=[1000, 1000], + letterHeight=40, + alignment="center", + ) + stims.append(stim_var) + + gen_value_stims(var.values, x_pos, y, offset) + + return stims + + +def generate_procedure_display(procedure: DisplayProcedure, position): + stim_procedure = visual.TextBox2( + WIN, + pos=position, + text=procedure.procedure, + size=[1000000, 1000], + letterHeight=40, + alignment="center", + ) + return stim_procedure + + +def generate_all_watersamples(n): + samples = [] + for _ in range(n): + samples.append(frensch_procedures.constrained_WaterSample()) + return samples + + +def run_blocked_trials(water_samples, procedure_keys): + results = {} + for proc_idx, proc in enumerate(procedure_keys): + for sample_idx, sample in enumerate(water_samples): + + if sample_idx % 6 == 0: + pause_after_trial.draw() + WIN.flip() + event.waitKeys(keyList=["space"]) + + cur_key = f"train_{sample_idx}" + if not cur_key in results.keys(): + results[cur_key] = {} + results[cur_key]["procedure_order"] = tuple(procedure_keys) + results[cur_key]["water_sample"] = sample.water_sample_dict() + + solid = DisplayVariable("Mineralien", [sample.solid]) + algae = DisplayVariable("Algen", [sample.algae]) + lime = DisplayVariable("Sandstein", sample.lime) + toxin = DisplayVariable("Gifte", sample.toxin) + x_positions = [-800, -400, 400, 800] + + stims = generate_variable_display([solid, algae, lime, toxin], x_positions) + + procedures = sample.procedure_dict() + + proc_x = -600 + proc_y = -100 + answ_x = 200 + answ_y = -100 + y_offset = 80 + + for prev in procedure_keys[:proc_idx]: + if not prev: + continue + p = DisplayProcedure(procedures[prev][1], procedures[prev][0]) + p = generate_procedure_display(p, (proc_x, proc_y)) + stims.append(p) + proc_y -= y_offset + + stim_answer_equals = visual.TextBox2( + WIN, + "=", + letterHeight=50, + pos=(answ_x - 100, answ_y), + size=[150, 70], + alignment="center", + ) + stims.append(stim_answer_equals) + + stim_answer_box = visual.TextBox2( + WIN, + results[f"train_{sample_idx}"][prev]["answer"], + letterHeight=50, + pos=(answ_x, answ_y), + size=[150, 70], + editable=True, + fillColor="white", + color="black", + alignment="center", + ) + stims.append(stim_answer_box) + answ_y -= y_offset + + p = DisplayProcedure(procedures[proc][1], procedures[proc][0]) + p = generate_procedure_display(p, (proc_x, proc_y)) + stims.append(p) + proc_y -= y_offset + + stim_answer_equals = visual.TextBox2( + WIN, + "=", + letterHeight=50, + pos=(answ_x - 100, answ_y), + size=[150, 70], + alignment="center", + ) + stims.append(stim_answer_equals) + + print(sample_idx) + stim_answer_box = visual.TextBox2( + WIN, + "", + letterHeight=50, + pos=(answ_x, answ_y), + size=[150, 70], + editable=True, + fillColor="white", + color="black", + alignment="center", + ) + stims.append(stim_answer_box) + answ_y -= y_offset + + not_finished = True + answer = "not answered" + start_time = core.monotonicClock.getTime() + while not_finished: + stim_answer_box.hasFocus = True + for stim in stims: + stim.draw() + WIN.flip() + answer = stim_answer_box.text + if "\n" in answer: + if answer[0].isdigit() and answer[1].isdigit(): + not_finished = False + else: + stim_answer_box.text = answer[:-1] + if len(answer) > 2: + stim_answer_box.text = stim_answer_box.text[:2] + answer_time = core.monotonicClock.getTime() - start_time + answer = (answer.replace("\n", ""), answer_time) + results[cur_key][proc] = {"answer": answer[0], "time": answer[1]} + + pause_new_proc.draw() + WIN.flip() + event.waitKeys(keyList=["space"]) + + return results + + +def run_trial(water_sample, procedure_keys: list, condition): + water_sample.print_all() + + if condition == "random": + overall = procedure_keys.pop() + random.shuffle(procedure_keys) + procedure_keys.append(overall) + + solid = DisplayVariable("Mineralien", [water_sample.solid]) + algae = DisplayVariable("Algen", [water_sample.algae]) + lime = DisplayVariable("Sandstein", water_sample.lime) + toxin = DisplayVariable("Gifte", water_sample.toxin) + x_positions = [-800, -400, 400, 800] + + stims = generate_variable_display([solid, algae, lime, toxin], x_positions) + + procedures = water_sample.procedure_dict() + + answers = [] + proc_x = -600 + proc_y = -100 + answ_x = 200 + answ_y = -100 + y_offset = 80 + for proc in procedure_keys: + p = DisplayProcedure(procedures[proc][1], procedures[proc][0]) + p = generate_procedure_display(p, (proc_x, proc_y)) + stims.append(p) + proc_y -= y_offset + + stim_answer_equals = visual.TextBox2( + WIN, + "=", + letterHeight=50, + pos=(answ_x - 100, answ_y), + size=[150, 70], + alignment="center", + ) + stims.append(stim_answer_equals) + + stim_answer_box = visual.TextBox2( + WIN, + "", + letterHeight=50, + pos=(answ_x, answ_y), + size=[150, 70], + editable=True, + fillColor="white", + color="black", + alignment="center", + ) + stims.append(stim_answer_box) + answ_y -= y_offset + + not_finished = True + answer = "not answered" + start_time = core.monotonicClock.getTime() + while not_finished: + stim_answer_box.hasFocus = True + for stim in stims: + stim.draw() + WIN.flip() + answer = stim_answer_box.text + if "\n" in answer: + if answer[0].isdigit() and answer[1].isdigit(): + not_finished = False + else: + stim_answer_box.text = answer[:-1] + if len(answer) > 2: + stim_answer_box.text = stim_answer_box.text[:2] + answer_time = core.monotonicClock.getTime() - start_time + answers.append((answer.replace("\n", ""), answer_time)) + + # event.waitKeys(keyList=["space"]) + + return tuple(answers), tuple(procedure_keys) + + +condition_dlg = gui.Dlg(title="Experiment Condition") +condition_dlg.addText("Condition") +condition_dlg.addField("condition") +CONDITION = condition_dlg.show()[0] + +assert CONDITION in ORDER_CONDITIONS + +pause = visual.TextBox2( + WIN, + """Drücken Sie die Leertaste um mit der nächsten Wasserprobe fortzufahren""", + letterHeight=50, + alignment="center", +) + +pause_new_proc = visual.TextBox2( + WIN, + """Drücken Sie die Leertaste um mit dem nächsten Kennwert fortzufahren""", + letterHeight=50, + alignment="center", +) + +pause_after_trial = visual.TextBox2( + WIN, + """Drücken Sie die Leertaste um fortzufahren""", + letterHeight=50, + alignment="center", +) + +intro = visual.TextBox2( + WIN, intro_text, letterHeight=40, alignment="center", size=(100000, 100000) +) +intro.draw() +WIN.flip() +event.waitKeys(keyList=["space"]) + +intro2 = visual.TextBox2( + WIN, intro2_text, letterHeight=40, alignment="center", size=(100000, 100000) +) +intro2.draw() +WIN.flip() +event.waitKeys(keyList=["space"]) + +train_procedures = PROCEDURE_KEYS[:-1] +random.shuffle(train_procedures) +transfer_procedure = train_procedures[-1] +train_procedures = train_procedures[:-1] +train_procedures.append(PROCEDURE_KEYS[-1]) + +all_samples = generate_all_watersamples(TRAIN_TRIALS + TEST_TRIALS) + +if CONDITION != "blocked": + results = {} + for i in range(TRAIN_TRIALS): + print(train_procedures) + answer, procedure_keys = run_trial(all_samples[i], train_procedures, CONDITION) + answer_dict = {} + answer_dict["procedure_order"] = procedure_keys + answer_dict["water_sample"] = all_samples[i].water_sample_dict() + for proc, key in zip(answer, procedure_keys): + answer_dict[key] = {"answer": proc[0], "time": proc[1]} + + results[f"train_{i}"] = answer_dict + + pause.draw() + WIN.flip() + event.waitKeys(keyList=["space"]) +else: + results = run_blocked_trials(all_samples[:TRAIN_TRIALS], train_procedures) + + +phase = visual.TextBox2( + WIN, + """Sie haben den ersten Teil geschafft! Der zweite Teil ist etwas kürzer als der erste + +Drücken Sie die Leertaste um anzufangen.""", + letterHeight=40, + alignment="center", +) +phase.draw() +WIN.flip() +event.waitKeys(keyList=["space"]) + +train_procedures[2] = transfer_procedure +for i in range(TEST_TRIALS): + print(train_procedures) + answer, procedure_keys = run_trial( + all_samples[TRAIN_TRIALS + i], train_procedures, "fixed" + ) + print(procedure_keys) + answer_dict = {} + answer_dict["procedure_order"] = procedure_keys + answer_dict["water_sample"] = all_samples[TRAIN_TRIALS + i].water_sample_dict() + for proc, key in zip(answer, procedure_keys): + answer_dict[key] = {"answer": proc[0], "time": proc[1]} + + results[f"test_{i}"] = answer_dict + + pause.draw() + WIN.flip() + event.waitKeys(keyList=["space"]) + +pprint(results) + +df = pd.DataFrame.from_dict(results, orient="index") +df.to_csv("vp_results.csv") + +with open("vp.pkl", "wb") as file: + pickle.dump(results, file) + +outro_text = "Das Experiment ist nun vorüber.\n\nVielen Dank für Ihre Teilnahme!" +outro = visual.TextBox2( + WIN, outro_text, letterHeight=40, alignment="center", size=(100000, 100000) +) +outro.draw() +WIN.flip() +event.waitKeys(keyList=["space"]) |