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The Psychology of Arithmetic

Chapter 22: MEASUREMENTS OF ABILITIES IN COMPUTATION
By Edward L. Thorndike
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About This Book

Applies newer dynamic psychology to elementary arithmetic, arguing that learning consists of forming connections between situations and responses; examines what constitutes numerical knowledge, computation skills, and problem solving; discusses measurement of arithmetical abilities with tests; analyzes habit formation, drill, amount and distribution of practice, sequencing of topics, and the strength of bonds; treats abstract thinking, reasoning, and use of concrete objects; addresses pupils' innate tendencies, interest, eye hygiene, oral, mental, and written methods, problem attitude, and individual differences, offering practical principles for organizing instruction and improving arithmetic teaching.

g.13
13914129
9131291424
23191929991321
28262614882923
2916151917191922

Woody ['16] has constructed his well-known tests on this principle, though he uses only one example at each step of difficulty instead of eight or ten as suggested above. His test, so far as addition of integers goes, is:—

SERIES A.     ADDITION SCALE (in part)

By Clifford Woody

(1)(2)(3)(4)(5)(6)(7)(8)(9)
2
3
 2
4
3
 17
2
 53
45
 72
26
 60
37
 3 + 1 = 2 + 5 + 1 = 20
10
2
30
25
(10)(11)(12)(13)(14)(15)(16)(17)(18)
21
33
35
 32
59
17
 43
1
2
13
 23
25
16
 25 + 42 = 100
33
45
201
46
 9
24
12
15
19
 199
194
295
156
——		 2563
1387
4954
2065
——
(19)(20)(21)(22)
$ .75
1.25
.49
——		 $12.50
16.75
15.75
——		 $8.00
5.75
2.33
4.16
.94
6.32
——		 547
197
685
678
456
393
525
240
152
——

In his original report, Woody gives no scheme for scoring an individual, wisely assuming that, with so few samples at each degree of difficulty, a pupil's score would be too unreliable for individual diagnosis. The test is reliable for a class; and for a class Woody used the degree of difficulty such that a stated fraction of the class can do the work correctly, if twenty minutes is allowed for the thirty-eight examples of the entire test.

The measurement of even so simple a matter as the efficiency of a pupil's responses to these tests in adding integers is really rather complex. There is first of all the problem of combining speed and accuracy into some single estimate. Stone gives no credit for a column unless it is correctly added. Courtis evades the difficulty by reporting both number done and number correct. The author's scheme, which gives specified weights to speed and accuracy at each step of the series, involves a rather intricate computation.

This difficulty of equating speed and accuracy in adding means precisely that we have inadequate notions of what the ability is that the elementary school should improve. Until, for example, we have decided whether, for a given group of pupils, fifteen Courtis attempts with ten right, is or is not a better achievement than ten Courtis attempts with nine right, we have not decided just what the business of the teacher of addition is, in the case of that group of pupils.

There is also the difficulty of comparing results when short and long columns are used. Correctness with a short column, say of five figures, testifies to knowledge of the process and to the power to do four successive single additions without error. Correctness with a long column, say of ten digits, testifies to knowledge of the process and to the power to do nine successive single additions without error. Now if a pupil's precision was such that on the average he made one mistake in eight single additions, he would get about half of his five-digit columns right and almost none of his ten-digit columns right. (He would do this, that is, if he added in the customary way. If he were taught to check results by repeated addition, by adding in half-columns and the like, his percentages of accurate answers might be greatly increased in both cases and be made approximately equal.) Length of column in a test of addition under ordinary conditions thus automatically overweights precision in the single additions as compared with knowledge of the process, and ability at carrying.

Further, in the case of a column of whatever size, the result as ordinarily scored does not distinguish between one, two, three, or more (up to the limit) errors in the single additions. Yet, obviously, a pupil who, adding with ten-digit columns, has half of his answer-figures wrong, probably often makes two or more errors within a column, whereas a pupil who has only one column-answer in ten wrong, probably almost never makes more than one error within a column. A short-column test is then advisable as a means of interpreting the results of a long-column test.

Finally, the choice of a short-column or of a long-column test is indicative of the measurer's notion of the kind of efficiency the world properly demands of the school. Twenty years ago the author would have been readier to accept a long-column test than he now is. In the world at large, long-column addition is being more and more done by machine, though it persists still in great frequency in the bookkeeping of weekly and monthly accounts in local groceries, butcher shops, and the like.

The search for a measure of ability to add thus puts the problem of speed versus precision, and of short-column versus long-column additions clearly before us. The latter problem has hardly been realized at all by the ordinary definitions of ability to add.

It may be said further that the measurement of ability to add gives the scientific student a shock by the lack of precision found everywhere in schools. Of what value is it to a graduate of the elementary school to be able to add with examples like those of the Courtis test, getting only eight out of ten right? Nobody would pay a computer for that ability. The pupil could not keep his own accounts with it. The supposed disciplinary value of habits of precision runs the risk of turning negative in such a case. It appears, at least to the author, imperative that checking should be taught and required until a pupil can add single columns of ten digits with not over one wrong answer in twenty columns. Speed is useful, especially indirectly as an indication of control of the separate higher-decade additions, but the social demand for addition below a certain standard of precision is nil, and its disciplinary value is nil or negative. This will be made a matter of further study later.

MEASUREMENTS OF ABILITIES IN COMPUTATION

Measurements of these abilities may be of two sorts—(1) of the speed and accuracy shown in doing one same sort of task, as illustrated by the Courtis test for addition shown on page 28; and (2) of how hard a task can be done perfectly (or with some specified precision) within a certain assigned time or less, as illustrated by the author's rough test for addition shown on pages 28 and 29, and by the Woody tests, when extended to include alternative forms.

The Courtis tests, originated as an improvement on the Stone tests and since elaborated by the persistent devotion of their author, are a standard instrument of the first sort for measuring the so-called 'fundamental' arithmetical abilities with integers. They are shown on this and the following page.

Tests of the second sort are the Woody tests, which include operations with integers, common and decimal fractions, and denominate numbers, the Ballou test for common fractions ['16], and the "Ladder" exercises of the Thorndike arithmetics. Some of these are shown on pages 36 to 41.

Courtis Test

Arithmetic.     Test No. 1.     Addition

Series B

You will be given eight minutes to find the answers to as many of these addition examples as possible. Write the answers on this paper directly underneath the examples. You are not expected to be able to do them all. You will be marked for both speed and accuracy, but it is more important to have your answers right than to try a great many examples.

927297136486384176277837
379925340765477783445882
756473988524881697682959
837983386140266200594603
924315353812679366481118
110661904466241851778781
854794547355796535849756
965177192834850323157222
344124439567733229953525
————————————————

and sixteen more addition examples of nine three-place numbers.

Courtis Test

Arithmetic.     Test No. 2.     Subtraction

Series B

You will be given four minutes to find the answers to as many of these subtraction examples as possible. Write the answers on this paper directly underneath the examples. You are not expected to be able to do them all. You will be marked for both speed and accuracy, but it is more important to have your answers right than to try a great many examples.

107795491750888249150005387939983
77197029574063941990156372207316
————————————————————

and twenty more tasks of the same sort.

Courtis Test

Arithmetic.     Test No. 3.     Multiplication

Series B

You will be given six minutes to work as many of these multiplication examples as possible. You are not expected to be able to do them all. Do your work directly on this paper; use no other. You will be marked for both speed and accuracy, but it is more important to get correct answers than to try a large number of examples.

82467843483734786482
29702831546
——————————

and twenty more multiplication examples of the same sort.

Courtis Test

Arithmetic.     Test No. 4.     Division

Series B

You will be given eight minutes to work as many of these division examples as possible. You are not expected to be able to do them all. Do your work directly on this paper; use no other. You will be marked for both speed and accuracy, but it is more important to get correct answers than to try a large number of examples.

25 ) 677594 ) 8535237 ) 999086 ) 80066

and twenty more division examples of the same sort.

SERIES B.     MULTIPLICATION SCALE

By Clifford Woody

(1)(3)(4)(5)
3 × 7 = 2 × 3 = 4 × 8 = 23
3
 
(8)(9)(11)(12)
50
3
 254
6
 1036
8
 5096
6
 
(13)(16)(18)(20)
8754
8
——		 7898
9
——		 24
234
——		 287
.05
——
 
(24)(26)(27)(29)
16    
258
——		 9742
59
——		 6.25
3.2
——		 18 × 2 =
 
(33)(35)(37)(38)
2½ × 3½ = 987¾
25  
———		 2¼ × 4½ × 1½ = .096318
.084    
——

SERIES B. DIVISION SCALE
By Clifford Woody

(1)(2)(7)(8)
3 ) 6    9 ) 27   4 ÷ 2 = 9 ) 0   
 
(11)(14)(15)(17)
2 ) 13    8 ) 5856   ¼ of 128 = 50 ÷ 7 =
 
(19)(23)(27)(28)
248 ÷ 7 = 23 ) 469    78 of 624 = .003 ) .0936  
 
(30)(34)(36)
34 ÷ 5 = 62.50 ÷ 1¼ = 9 ) 69 lbs. 9 oz.

Ballou Test

Addition of Fractions

Test 1Test 2
(1)   ¼
¼
 (2)   314
114
 (1)   13
16
 (2)   27
314
Test 3Test 4
(1)   35
1115
 (2)   56
12
 (1)   17
910
 (2)   79
14
Test 5Test 6
(1)   110
16
 (2)   49
512
 (1)   16
910
 (2)   56
38

An Addition Ladder [Thorndike, '17, III, 5]

Begin at the bottom of the ladder. See if you can climb to the top without making a mistake. Be sure to copy the numbers correctly.

Step 6.a. Add 113 yd., 78 yd., 1¼ yd., 34 yd., 78 yd., and 1½ yd.
b. Add 62½¢, 6623¢, 56¼¢, 60¢, and 62½¢.
c. Add 1516, 1932, 138, 11132, and 1716.
d. Add 113 yd., 1¼ yd., 1½ yd., 2 yd., 34 yd., and 23 yd.
 
Step 5.a. Add 4 ft. 6½ in., 53¼ in., 5 ft. ½ in., 56¾ in., and 5 ft.
b. Add 7 lb., 6 lb. 11 oz., 7½ lb., 6 lb. 4½ oz., and 8½ lb.
c. Add 1 hr. 6 min. 20 sec., 58 min. 15 sec., 1 hr. 4 min., and 55 min.
d. Add 7 dollars, 13 half dollars, 21 quarters, 17 dimes, and 19 nickels.
 
Step 4.a. Add .05½, .06, .04¾, .02¾, and .05¼.
b. Add .3313, .12½, .18, .1623, .0813 and .15.
c. Add .0813, .06¼, .21, .03¾, and .1623.
d. Add .62, .64½, .6623, .10¼, and .68.
 
Step 3.a. Add 7¼, 6½, 838, 5¾, 958 and 378.
b. Add 458, 12, 7½, 8¾, 6 and 5¼.
c. Add 9¾, 578, 418, 6½, 7, 358.
d. Add 12, 8½, 713, 5, 623, and 9½.
 
Step 2.a. Add 12.04, .96, 4.7, 9.625, 3.25, and 20.
b. Add .58, 6.03, .079, 4.206, 2.75, and 10.4.
c. Add 52, 29.8, 41.07, 1.913, 2.6, and 110.
d. Add 29.7, 315, 26.75, 19.004, 8.793, and 20.05.
 
Step 1.a. Add 1035, 1115, 1045, 11, 1125, 1035, and 11.
b. Add 738, 658, 8, 918, 778, 538, and 818.
c. Add 21½, 18¾, 31½, 19¼, 17¼, 22, and 16½.
d. Add 14512, 12712, 91112, 6112, and 5.

A Subtraction Ladder [Thorndike, '17, III, 11]

Step 9.
a. 2.16 mi. − 1¾ mi.
c. 2 min. 10½ sec. − 93.4 sec.
e. 10 gal. 2½ qt. − 4.623 gal.		 b. 5.72 ft. − 5 ft. 3 in.
d. 30.28 A. − 1015 A.
 
 
Step 8.abcde
25712
1234
———		 1014
713
———		 9516
638 
———		 5716
234 
———		 423
134
———
 
Step 7.abcde
2834
1618
———		 4012
1438
———		 1014
612
———		 2413
1112
———		 3712
1434
———
 
Step 6.abcde
1013
423
———		 714
234
———		 1518
638
———		 1215
1145
———		 4116
2716
———
 
Step 5.abcde
5845
5215
———		 6623
3313
———		 2878
758
———		 62½
37½
——		 9712
4512
——
 
Step 4.
a. 4 hr. − 2 hr. 17 min.
c. 1 lb. 5 oz. − 13 oz.
e. 1 bu. − 1 pk.		 b. 4 lb. 7 oz. − 2 lb. 11 oz.
d. 7 ft. − 2 ft. 8 in.
 
 
Step 3.abcde
92      mi.
84.15 mi.
————		 6735 mi.
6689 mi.
————		 $3 − 89¢

————		 28.4   mi.
18.04 mi.
————		 $508.40
208.62
————
 
Step 2.abcde
$25.00
9.36
———		 $100.00
71.28
———		 $750.00
736.50
———		 6124 sq. mi.
2494 sq. mi.
—————		 7846 sq. mi.
2789 sq. mi.
—————
 
Step 1.abcde
$18.64
7.40
———		 $25.39
13.37
———		 $56.70
45.60
———		 819.4 mi.
209.2 mi.
————		 67.55 mi.
36.14 mi.
————

An Average Ladder [Thorndike, '17, III, 132]

Find the average of the quantities on each line. Begin with Step 1. Climb to the top without making a mistake. Be sure to copy the numbers correctly. Extend the division to two decimal places if necessary.

Step 6.a. 223, 178, 2¾, 4¼, 358, 3½
b. 62½¢, 6623¢, 40¢, 8313¢, $1.75, $2.25
c. 31116, 3932, 338, 31732, 3716
d. .17, 19, .1623, .15½, .23¼, .18
 
Step 5.a. 5 ft. 3½ in., 61¼ in., 58¾ in., 4 ft. 11 in.
b. 6 lb. 9 oz., 6 lb. 11 oz., 7¼ lb., 738 lb.
c. 1 hr. 4 min. 40 sec., 58 min. 35 sec., 1¼ hr.
d. 2.8 miles, 3½ miles, 2.72 miles
 
Step 4.a. .03½, .06, .04¾, .05½, .05¼
b. .043, .045, .049, .047, .046, .045
c. 2.20, .87½, 1.18, .93¾, 1.2925, .80
d. .14½, .12½, .3313, .1623, .15, .17
 
Step 3.a. 5¼, 4½, 838, 7¾, 658, 938
b. 958, 12, 8½, 8¾, 6, 5¼, 9
c. 938, 5¾, 418, 7½, 6
d. 11, 9½, 1013, 13, 1623, 9½
 
Step 2.a. 13.05, .97, 4.8, 10.625, 3.37
b. 1.48, 7.02, .93, 5.307, 4.1, 7, 10.4
c. 68, 71.4, 59.8, 112, 96.1, 79.8
d. 2.079, 3.908, 4.165, 2.74
 
Step 1.a. 4, 9½, 6, 5, 7½, 8, 10, 9
b. 6, 5, 3.9, 7.1, 8
c. 1086, 1141, 1059, 1302, 1284
d. $100.82, $206.49, $317.25, $244.73

As such tests are widened to cover the whole task of the elementary school in respect to arithmetic, and accepted by competent authorities as adequate measures of achievement in computing, they will give, as has been said, a working definition of the task. The reader will observe, for example, that work such as the following, though still found in many textbooks and classrooms, does not, in general, appear in the modern tests and scales.

Reduce the following improper fractions to mixed numbers:—

1913         4321         17625         19814

Reduce to integral or mixed numbers:—

6138137         213467         413413         697225

Simplify:—

34   of   89   of   35   of   1522

Reduce to lowest terms:—

357527         264312         492779         418874         8541769         30735         44242         77847         18243         96224

Find differences:—

627
3114
——		 8511
517
——		 8413
3713
——		 514
21114
——		 718
217
——

Square:—

23         45         57         69         1011         1213         27         1516         1920         1718         2530         4153

Multiply:—

211 × 33         32 × 314         39 × 213         60 × 1128         77 × 411         63 × 227
54 × 845         65 × 313         3441621    43227

MEASUREMENTS OF ABILITY IN APPLIED ARITHMETIC: THE SOLUTION OF PROBLEMS

Stone ['08] measured achievement with the following problems, fifteen minutes being the time allowed.

"Solve as many of the following problems as you have time for; work them in order as numbered:

1. If you buy 2 tablets at 7 cents each and a book for 65 cents, how much change should you receive from a two-dollar bill?

2. John sold 4 Saturday Evening Posts at 5 cents each. He kept 12 the money and with the other 12 he bought Sunday papers at 2 cents each. How many did he buy?

3. If James had 4 times as much money as George, he would have $16. How much money has George?

4. How many pencils can you buy for 50 cents at the rate of 2 for 5 cents? '

5. The uniforms for a baseball nine cost $2.50 each. The shoes cost $2 a pair. What was the total cost of uniforms and shoes for the nine?

6. In the schools of a certain city there are 2200 pupils; 12 are in the primary grades, 14 in the grammar grades, 18 in the high school, and the rest in the night school. How many pupils are there in the night school?

7. If 3½ tons of coal cost $21, what will 5½ tons cost?

8. A news dealer bought some magazines for $1. He sold them for $1.20, gaining 5 cents on each magazine. How many magazines were there?

9. A girl spent 18 of her money for car fare, and three times as much for clothes. Half of what she had left was 80 cents. How much money did she have at first?

10. Two girls receive $2.10 for making buttonholes. One makes 42, the other 28. How shall they divide the money?

11. Mr. Brown paid one third of the cost of a building; Mr. Johnson paid 12 the cost. Mr. Johnson received $500 more annual rent than Mr. Brown. How much did each receive?

12. A freight train left Albany for New York at 6 o'clock. An express left on the same track at 8 o'clock. It went at the rate of 40 miles an hour. At what time of day will it overtake the freight train if the freight train stops after it has gone 56 miles?"

The criteria he had in mind in selecting the problems were as follows:—

"The main purpose of the reasoning test is the determination of the ability of VI A children to reason in arithmetic. To this end, the problems, as selected and arranged, are meant to embody the following conditions:—

1. Situations equally concrete to all VI A children.

2. Graduated difficulties.
a. As to arithmetical thinking.
b. As to familiarity with the situation presented.

3. The omission of
a. Large numbers.
b. Particular memory requirements.
c. Catch problems.
d. All subject matter except whole numbers, fractions, and United States money.

The test is purposely so long that only very rarely did any pupil fully complete it in the fifteen minute limit."

Credits were given of 1, for each of the first five problems, 1.4, 1.2, and 1.6 respectively for problems 6, 7, and 8, and of 2 for each of the others.

Courtis sought to improve the Stone test of problem-solving, replacing it by the two tests reproduced below.

ARITHMETIC—Test No. 6.       Speed Test—Reasoning

Do not work the following examples. Read each example through, make up your mind what operation you would use if you were going to work it, then write the name of the operation selected in the blank space after the example. Use the following abbreviations:—"Add." for addition, "Sub." for subtraction, "Mul." for multiplication, and "Div." for division.

 Operation   
1. A girl brought a collection of 37 colored postal cards to school one day, and gave away 19 cards to her friends. How many cards did she have left to take home?     
2. Five boys played marbles. When the game was over, each boy had the same number of marbles. If there were 45 marbles altogether, how many did each boy have?     
3. A girl, watching from a window, saw 27 automobiles pass the school the first hour, and 33 the second. How many autos passed by the school in the two hours?     
4. In a certain school there were eight rooms and each room had seats for 50 children. When all the places were taken, how many children were there in the school?     
5. A club of boys sent their treasurer to buy baseballs. They gave him $3.15 to spend. How many balls did they expect him to buy, if the balls cost 45¢. apiece?     
6. A teacher weighed all the girls in a certain grade. If one girl weighed 79 pounds and another 110 pounds, how many pounds heavier was one girl than the other?     
7. A girl wanted to buy a 5-pound box of candy to give as a present to a friend. She decided to get the kind worth 35¢. a pound. What did she pay for the present?     
8. One day in vacation a boy went on a fishing trip and caught 12 fish in the morning, and 7 in the afternoon. How many fish did he catch altogether?     
9. A boy lived 15 blocks east of a school; his chum lived on the same street, but 11 blocks west of the school. How many blocks apart were the two boys' houses?     
10. A girl was 5 times as strong as her small sister. If the little girl could lift a weight of 20 pounds, how large a weight could the older girl lift?     
11. The children of a school gave a sleigh-ride party. There were 270 children to go on the ride and each sleigh held 30 children. How many sleighs were needed?     
12. In September there were 43 children in the eighth grade of a certain school; by June there were 59. How many children entered the grade during the year?     
13. A girl who lived 17 blocks away walked to school and back twice a day. What was the total number of blocks the girl walked each day in going to and from school?     
14. A boy who made 67¢. a day carrying papers, was hired to run on a long errand for which he received 50¢. What was the total amount the boy earned that day?     
Total Right     

(Two more similar problems follow.)

Test 6 and Test 8 are from the Courtis Standard Test. Used by permission of S. A. Courtis.

ARITHMETIC—Test No. 8.       Reasoning