Top 10k strings from Study Physics - 13 years+ (1983)(Scisoft)(Side B).tzx in <root> / bin / z80 / software / Sinclair Spectrum Collection TOSEC.exe / Sinclair ZX Spectrum - Utilities & Educational / Sinclair ZX Spectrum - Utilities & Educational - [TZX] (TOSEC-v2007-01-01) /
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16 ;"PRESS ANY KEY TO CONTINUE." 12 ;"YOU HAVE GAINED SOME POINTS." 12 ;"WELL DONE" 5 )=" WORK DONE" 4 M$(F)=E$(E) 4 C$(W5)=M$(5 4 C$(W4)=M$(4 4 C$(W3)=M$(3 4 C$(W2)=M$(2 4 C$(W1)=M$(1 4 C$(H)=E$(D) 4 ;"YOUR SCORE" 4 ;"YOUR POINT SCORE IS NOW :- ";B+X 4 ;"YOU WILL NOW BE GIVEN SOME" 4 ;"YOU MUST PRESS EITHER Y OR N." 4 ;"YOU HAVE REACHED 100 POINTS." 4 ;"YOU HAVE NOW COMPLETED" 4 ;"YOU BEGIN AT ZERO." 4 ;"WRONG ANSWERS" 4 ;"WOULD YOU LIKE FURTHER EQUATIONS" 4 ;"WHEN YOU REACH 100 PTS YOU HAVE" 4 ;"WELL DONE YOUR ANSWER IS CORRECT" 4 ;"TYPE IN YOUR NAME" 4 ;"TYPE IN THE NUMBER THAT YOU" 4 ;"TOO LONG AT ANY ONE SESSION" 4 ;"TO GAIN POINTS YOU MUST SCORE" 4 ;"TO ANSWER THE QUESTIONS WITHOUT" 4 ;"THIS REVISION PROGRAM." 4 ;"THINK IS CORRECT." 4 ;"THEN PRESS ENTER TO CONTINUE." 4 ;"THE CORRECT ANSWER IS :-" 4 ;"SCISOFT" 4 ;"SCIENCE STUDENTS" 4 ;"RIGHT ANSWERS": 4 ;"REVISION QUESTIONS" 4 ;"REALLY KNOWING THE EQUATIONS." 4 ;"PRESS Y FOR YES OR N FOR NO" 4 ;"PRESS Y FOR YES OR N FOR NO" 4 ;"PRESS ANY KEY FOR THE NEXT" 4 ;"POINT SCORE" 4 ;"PHYSICS" 4 ;"NOW PRESS YOUR CORRECT GRADE" 4 ;"MULTIPLE CHOICE QUESTIONS." 4 ;"IF YOU DO THEN YOU WILL BE ABLE" 4 ;"IF THIS IS YOUR FIRST TIME THEN" 4 ;"HELLO "; 4 ;"HAVE PUSHED A NUMBER BETWEEN" 4 ;"GOODBYE ";A$ 4 ;"FOLLOWED BY ENTER." 4 ;"FIRST TYPE IN YOUR POINT SCORE." 4 ;"EQUATIONS USED IN THIS PROGRAM?" 4 ;"EQUATION." 4 ;"EDUCATIONAL PROGRAMS" 4 ;"COMPLETED THIS REVISION SERIES." 4 ;"AT LEAST SEVEN OUT OF TEN." 4 ;"9 OUT OF 10 .........16 POINTS" 4 ;"8 OUT OF 10 .........10 POINTS" 4 ;"7 OUT OF 10 ......... 6 POINTS" 4 ;"5. ";C$(5 4 ;"4. ";C$(4 4 ;"3. ";C$(3 4 ;"2. ";C$(2 4 ;"10 OUT OF 10 .........20 POINTS" 4 ;"1. ";C$(1 4 ;"0 AND 100" 4 ;" WOULD YOU LIKE A LIST OF THE" 4 ;" YOU MUST PRESS EITHER Y OR N." 4 )=" REFRACTIVE INDEX" 4 )=" MAGNIFICATION" 4 )=" HEAT GIVEN OUT" 4 )=" FREQUENCY" 4 "YOU MUST PRESS A KEY BETWEEN 1 AND 5" 4 "YOU HAVE PUSHED ";B$;", YOU SHOULD" 3 ;"YOU ARE ADVISED NOT TO SPEND" 3 )=" VELOCITY RATIO" 3 )=" CURRENT" 2 ;"NO YOUR ANSWER IS WRONG." 2 ;"N0 YOUR ANSWER IS WRONG." 2 )="MASS x SPECIFIC LATENT HEAT =" 2 )="FORCE / AREA =" 2 )=" TEMPERATURE CHANGE" 2 )=" SPECIFIC HEAT CAPACITY" 2 )=" PRESSURE" 2 )=" QUANTITY OF ELECTRICITY" 2 )=" POWER" 2 )=" POTENTIAL DIFFERENCE" 2 )=" FORCE" 2 )=" EFFICIENCY" 1 VELOCITY OF WAVE IN FIRST MEDIUM/ VELOCITY OF WAVE IN SECOND MEDIUM. = A CONSTANT x THE SQ. ROOT OF (1 / MASS PER UNIT LENGTH OF A STRETCHED STRING) = IMAGE DISTANCE FROM LENS / OBJECT DISTANCE FROM LENS = REFRACTIVE INDEX x SINE OF THE ANGLE OF REFRACTION = FREQUENCY x WAVELENGTH = (IMAGE HEIGHT x OBJECT DISTANCE FROM PINHOLE) / OBJECT HEIGHT = HEIGHT OF IMAGE / HEIGHT OF OBJECT = SINE OF THE ANGLE OF INCIDENCE /SINE OF THE ANGLE OF REFRACTION = SINE OF THE ANGLE OF INCIDENCE /REFRACTIVE INDEX = WAVE VELOCITY / WAVELENGTH = IMAGE DISTANCE FROM PINHOLE / OBJECT DISTANCE FROM PINHOLE = 1 / SINE OF THE CRITICAL ANGLE = 1 PROG1 1 EXPANSION / (ORIGINAL LENGTH x RISE IN TEMPERATURE) = (PRESSURE x VOLUME) / A CONSTANT = MASS x SPECIFIC HEAT CAPACITY x TEMPERATURE CHANGE = HEAT GIVEN OUT / SPECIFIC LATENT HEAT = FORCE / AREA = (TEMPERATURE x A CONSTANT) / VOLUME = LINEAR EXPANSIVITY x ORIGINAL LENGTH x RISE IN TEMPERATURE = (FORCE OF GRAVITY x HEIGHT FALLEN) / TEMPERATURE RISE = MASS x SPECIFIC LATENT HEAT = HEAT TAKEN IN / HEAT CAPACITY = HEAT GIVEN OUT / (MASS x SPECIFIC HEAT CAPACITY) = (TEMPERATURE x A CONSTANT) / PRESSURE = EXPANSION / (ORIGINAL LENGTH x LINEAR EXPANSIVITY = 1 EQMECH - 1 EQLIGHT 1 EQHEAT c. 1 EQELEC 1 EQ 1 Created with Ramsoft MakeTZX 1 AVERAGE SPEED x TIME TAKEN = DISTANCE MOVED / TIME TAKEN = INITIAL VELOCITY + (ACCELERATION x TIME TAKEN) = DISTANCE MOVED IN A PARTICULAR DIRECTION / TIME TAKEN = CHANGE IN VELOCITY / TIME TAKEN = WORK OUTPUT x 100 / WORK INPUT = AREA OF RAM PISTON / AREA OF PUMP PISTON = CHANGE IN MOMENTUM / TIME TAKEN FOR THIS CHANGE = FORCE x DISTANCE MOVED IN DIRECTION OF FORCE = ENERGY TRANSFERRED / TIME TAKEN = LOAD / EFFORT = DISTANCE MOVED BY EFFORT / DISTANCE MOVED BY LOAD = MASS x ACCELERATION = 1 ;"YOU ARE ADVISED NOT TO SPEND" 1 ;"MECHANICS" 1 ;"LIGHT & SOUND" 1 ;"HEAT & PRESSURE" 1 ;"ELECTRICITY" 1 8888888888888888888888888888888888888888888888888888888888888888 1 )="WORK OUTPUT x 100 / WORK INPUT =" 1 )="WORK DONE / TIME TAKEN =" 1 )="WORK DONE / POTENTIAL DIFFERENCE =" 1 )="WAVE VELOCITY / WAVELENGTH =" 1 )="WAVE VELOCITY / FREQUENCY =" 1 )="VELOCITY OF WAVE IN FIRST MEDIUM/ VELOCITY OF WAVE IN SECOND MEDIUM. =" 1 )="TOTAL QUANTITY OF ELECTRICITY x POTENTIAL DIFFERENCE =" 1 )="TOTAL QUANTITY OF ELECTRICITY / TIME =" 1 )="TIME x CURRENT =" 1 )="SINE OF THE ANGLE OF INCIDENCE /REFRACTIVE INDEX =" 1 )="SINE OF THE ANGLE OF INCIDENCE /SINE OF THE ANGLE OF REFRACTION =" 1 )="RESISTANCE x CURRENT =" 1 )="REFRACTIVE INDEX x SINE OF THE ANGLE OF REFRACTION =" 1 )="REFRACTIVE INDEX - AIR TO WATER x VELOCITY OF LIGHT IN WATER =" 1 )="REAL DEPTH / APPARENT DEPTH =" 1 )="PRESSURE x AREA =" 1 )="POWER / POTENTIAL DIFFERENCE =" 1 )="POWER / CURRENT =" 1 )="POTENTIAL x CAPACITANCE =" 1 )="POTENTIAL DIFFERENCE x CURRENT xTIME =" 1 )="POTENTIAL DIFFERENCE x CURRENT =" 1 )="POTENTIAL DIFFERENCE / CURRENT =" 1 )="POTENTIAL DIFFERENCE / RESISTANCE =" 1 )="NUMBER OF TEETH IN DRIVEN WHEEL / NUMBER OF TEETH IN DRIVING WHEEL =" 1 )="MECHANICAL ADVANTAGE x 100 / VELOCITY RATIO =" 1 )="MASS x VELOCITY =" 1 )="MASS x SPECIFIC HEAT CAPACITY x TEMPERATURE CHANGE =" 1 )="MASS x ACCELERATION =" 1 )="MASS / VOLUME =" 1 )="LOAD x DISTANCE LOAD MOVES / EFFORT x DISTANCE EFFORT MOVES =" 1 )="LOAD / EFFORT =" 1 )="LINEAR EXPANSIVITY x ORIGINAL LENGTH x RISE IN TEMPERATURE =" 1 )="INITIAL VELOCITY + (ACCELERATION x TIME TAKEN) =" 1 )="IMAGE DISTANCE FROM PINHOLE / OBJECT DISTANCE FROM PINHOLE =" 1 )="IMAGE DISTANCE FROM MIRROR / OBJECT DISTANCE FROM MIRROR =" 1 )="IMAGE DISTANCE FROM LENS / OBJECT DISTANCE FROM LENS =" 1 )="HEIGHT OF IMAGE / HEIGHT OF OBJECT =" 1 )="HEAT TAKEN IN / HEAT CAPACITY =" 1 )="HEAT TAKEN IN / (MASS x CHANGE IN TEMPERATURE =" 1 )="HEAT GIVEN OUT / TEMPERATURE CHANGE =" 1 )="HEAT GIVEN OUT / SPECIFIC LATENT HEAT =" 1 )="HEAT GIVEN OUT / (MASS x SPECIFIC HEAT CAPACITY) =" 1 )="HEAT GIVEN OUT / (CHANGE IN TEMPERATURE x SPECIFIC HEAT CAPACITY) =" 1 )="HEAT ENERGY GIVEN OUT / MASS =" 1 )="HEAT CAPACITY x TEMPERATURE CHANGE =" 1 )="FREQUENCY x WAVELENGTH =" 1 )="FORCE x DISTANCE MOVED IN DIRECTION OF FORCE =" 1 )="EXPANSION / (ORIGINAL LENGTH x RISE IN TEMPERATURE) =" 1 )="EXPANSION / (ORIGINAL LENGTH x LINEAR EXPANSIVITY =" 1 )="ENERGY TRANSFERRED / TIME TAKEN =" 1 )="EMF OF CELL / TOTAL RESISTANCE =" 1 )="DISTANCE MOVED IN A PARTICULAR DIRECTION / TIME TAKEN =" 1 )="DISTANCE MOVED BY EFFORT / DISTANCE MOVED BY LOAD =" 1 )="DISTANCE MOVED / TIME TAKEN =" 1 )="CURRENT x CURRENT x TIME x RESISTANCE =" 1 )="CURRENT FLOWING IN CIRCUIT x TOTAL RESISTANCE =" 1 )="CHARGE / POTENTIAL =" 1 )="CHANGE IN VELOCITY / TIME TAKEN =" 1 )="CHANGE IN MOMENTUM / TIME TAKEN FOR THIS CHANGE =" 1 )="AVERAGE SPEED x TIME TAKEN =" 1 )="AREA OF RAM PISTON / AREA OF PUMP PISTON =" 1 )="ANGLE OF REFLECTION =" 1 )="A CONSTANT x THE SQ. ROOT OF THETENSION IN A STRETCHED STRING =" 1 )="A CONSTANT x THE SQ. ROOT OF (1 / MASS PER UNIT LENGTH OF A STRETCHED STRING) =" 1 )="1 / SINE OF THE CRITICAL ANGLE =" 1 )="(TIME x POTENTIAL DIFFERENCE x POTENTIAL DIFFERENCE) / RESISTANCE =" 1 )="(TEMPERATURE x A CONSTANT) / VOLUME =" 1 )="(TEMPERATURE x A CONSTANT) / PRESSURE =" 1 )="(PRESSURE x VOLUME) / A CONSTANT =" 1 )="(No. OF TURNS IN SECONDARY x PRIMARY EMF) / No. OF TURNS IN PRIMARY =" 1 )="(No. OF TURNS IN PRIMARY x SECONDARY EMF) / No. OF TURNS INSECONDARY =" 1 )="(IMAGE HEIGHT x OBJECT DISTANCE FROM PINHOLE) / OBJECT HEIGHT =" 1 )="(IMAGE DISTANCE FROM PINHOLE x OBJECT HEIGHT) / OBJECT DISTANCEFROM PINHOLE =" 1 )="(FORCE OF GRAVITY x HEIGHT FALLEN) / TEMPERATURE RISE =" 1 )="(FORCE OF GRAVITY x HEIGHT FALLEN) / SPECIFIC HEAT CAPACITY =" 1 )="(1 / LENGTH OF A STRETCHED STRING) x A CONSTANT =" 1 )=" WAVELENGTH" 1 )=" WAVE VELOCITY" 1 )=" VOLUME" 1 )=" VELOCITY OF LIGHT IN AIR" 1 )=" TEMPERATURE" 1 )=" TEMPERATURE RISE" 1 )=" SPECIFIC LATENT HEAT" 1 )=" SINE OF THE REFRACTED ANGLE" 1 )=" SINE OF THE INCIDENT ANGLE" 1 )=" RISE IN TEMPERATURE" 1 )=" LINEAR EXPANSIVITY" 1 )=" IMAGE DISTANCE FROM PINHOLE" 1 )=" HEIGHT OF IMAGE" 1 )=" HEAT CAPACITY" 1 )=" EXPANSION" 1 )=" ANGLE OF INCIDENCE" 1 )=" VELOCITY" 1 )=" THRUST" 1 )=" SECONDARY EMF" 1 )=" RESISTANCE" 1 )=" PRIMARY EMF" 1 )=" PRESSURE" 1 )=" MOMENTUM" 1 )=" MECHANICAL ADVANTAGE" 1 )=" FINAL VELOCITY" 1 )=" EMF OF CELL" 1 )=" EFFICIENCY PERCENTAGE" 1 )=" DISTANCE" 1 )=" DENSITY" 1 )=" CURRENT IN A CIRCUIT" 1 )=" CHARGE" 1 )=" CAPACITANCE" 1 )=" AVERAGE SPEED" 1 )=" AVERAGE POWER" 1 )=" ACCELERATION" 1 (No. OF TURNS IN SECONDARY x PRIMARY EMF) / No. OF TURNS IN PRIMARY = RESISTANCE x CURRENT = TIME x CURRENT = POTENTIAL DIFFERENCE / RESISTANCE = TOTAL QUANTITY OF ELECTRICITY x POTENTIAL DIFFERENCE = POTENTIAL DIFFERENCE x CURRENT xTIME = EMF OF CELL / TOTAL RESISTANCE = WORK DONE / POTENTIAL DIFFERENCE = POWER / CURRENT = (No. OF TURNS IN PRIMARY x SECONDARY EMF) / No. OF TURNS INSECONDARY = POTENTIAL DIFFERENCE / CURRENT = CURRENT FLOWING IN CIRCUIT x TOTAL RESISTANCE = CURRENT x CURRENT x TIME x RESISTANCE = 1 REFRACTIVE INDEX FREQUENCY MAGNIFICATION SINE OF THE INCIDENT ANGLE WAVE VELOCITY IMAGE DISTANCE FROM PINHOLE MAGNIFICATION REFRACTIVE INDEX SINE OF THE REFRACTED ANGLE FREQUENCY MAGNIFICATION REFRACTIVE INDEX HEIGHT OF IMAGE FREQUENCY VELOCITY OF LIGHT IN AIR MAGNIFICATION REFRACTIVE INDEX WAVELENGTH FREQUENCY ANGLE OF INCIDENCE 1 MASS HEAT GIVEN OUT HEAT GIVEN OUT HEAT GIVEN OUT HEAT GIVEN OUT 1 LINEAR EXPANSIVITY TEMPERATURE HEAT GIVEN OUT MASS PRESSURE PRESSURE EXPANSION SPECIFIC HEAT CAPACITY HEAT GIVEN OUT TEMPERATURE CHANGE TEMPERATURE CHANGE VOLUME RISE IN TEMPERATURE SPECIFIC LATENT HEAT HEAT GIVEN OUT MASS HEAT GIVEN OUT HEAT CAPACITY TEMPERATURE RISE SPECIFIC HEAT CAPACITY 1 HEIGHT OF IMAGE FREQUENCY WAVE VELOCITY MAGNIFICATION ANGLE OF INCIDENCE f 1 HEIGHT OF IMAGE ANGLE OF INCIDENCE FREQUENCY WAVE VELOCITY MAGNIFICATION 1 WORK DONE EMF OF CELL RESISTANCE CURRENT POWER f 1 SECONDARY EMF POTENTIAL DIFFERENCE QUANTITY OF ELECTRICITY CURRENT WORK DONE WORK DONE CURRENT IN A CIRCUIT QUANTITY OF ELECTRICITY POTENTIAL DIFFERENCE PRIMARY EMF RESISTANCE EMF OF CELL WORK DONE CURRENT POWER CHARGE WORK DONE CURRENT POWER CAPACITANCE 1 FORCE MOMENTUM FINAL VELOCITY AVERAGE POWER MECHANICAL ADVANTAGE f 1 FORCE AVERAGE POWER MOMENTUM MECHANICAL ADVANTAGE FINAL VELOCITY 1 EMF OF CELL POWER WORK DONE RESISTANCE CURRENT 1 DISTANCE AVERAGE SPEED FINAL VELOCITY VELOCITY ACCELERATION EFFICIENCY PERCENTAGE VELOCITY RATIO FORCE WORK DONE AVERAGE POWER MECHANICAL ADVANTAGE VELOCITY RATIO FORCE EFFICIENCY MOMENTUM EFFICIENCY VELOCITY RATIO THRUST PRESSURE DENSITY 1 f