Non-Rote Memory

Second-grade classes are usually taught to skip-count by twos, fives, and tens as preparation for learning to multiply and divide. That is, the teachers give instructions with that goal in mind, but typically not all of the students reach the goal. Some of them memorize the words, but fail to understand the idea behind them, which leads to failure with multiplication and division when they are presented. And some do not even memorize the words correctly. Why is that? I have observed several situations which shed light on this question, which I would like to share with you.

Consider the experience of Jose, a seventh-grader who wanted to show his study hall teacher how fast he could count by twos from zero to twenty-four. He enthusiastically began: “Two, four, six, eight, ten…, eleven?, no…, twelve?, no…, thirteen?, no…” He asked if he could begin again. He seemed to think that—like riding a bike up a steep hill—if he could get going really fast, the right words would flow and he would make it to the top (to twenty-four). He started over several times, but never got past ten, where his memory always failed him. He apparently had no idea how those counting words came to be in the first place; so with no concept of what he was doing, he could not extend the pattern. He could, however, quite successfully repeat from memory a limited number of words that had no meaning to him.

Consider the case of a high-school special ed student, who was attempting to count objects that were grouped in fives. She began, “Five, ten…,” and then went blank. The teacher’s aide mouthed the first sound of the next word in the pattern, to cue her next response: “Ffff…” “Ff…four,” said the girl. “No. Five, ten, ffff…,” intoned the adult. “Ff…fourteen?” replied the child. She could not successfully repeat from memory a limited number of words that had no meaning to her.

And there is the case of Robin, a sixth-grader who recognized that an array of objects was arranged in groups of five, and counted them like this: “Five, ten, fifteen, twenty, twenty-two, twenty-four, twenty-six, twenty-eight!” She understood that she should be skip-counting by fives, but did not realize that she had suddenly switched from counting by fives to counting by twos. A similar thing happened with a middle-school boy, who counted, “Five, ten, fifteen, twenty, thirty, forty, etc.” He unknowingly switched from fives to tens.

I had two experiences myself with memorizing as a high-school student. Our cheerleaders came back from a special summer camp all fired up to teach us some new cheers. The first one they taught us was composed entirely of nonsense syllables. It was crazy, funny, and we could say it! What did it mean? Nothing. Not less crazy was the day that my Algebra teacher demanded that our class memorize a formula, which she wrote on the board: “y = mx + b.” I raised my hand and asked what it meant. “Don’t worry about that,” she said. “Just memorize it now, and we’ll learn what it means later.” Like the nonsense cheer that we learned during the pep rally, we could say the formula. And what did it mean? Nothing. It was crazy, but it wasn’t fun.

Memorizing musical words can be quite charming and engaging—although equally nonsensical. Many Beatles fans can still sing from memory the French words to “Michelle,” but they don’t know what they mean. Thousands of elementary school children enthusiastically sing Frère Jacques every year without understanding the lyrics they repeat. They have fluent recall of the words, but cannot use them to develop their understanding of the language. In fact, millions of American children annually memorize the words to the Pledge to the Flag—which is in English—but they don’t know what many of those words mean, either. And when they proudly recite, “…and to the republic for Richard stands,” they don’t think to ask who Richard is.

I once witnessed an entire class of kindergartners perform a feat of instantaneous linguistic mimicry. Their music teacher told them to listen quietly while he sang them a new song. To his surprise, they started singing the new song right along with him—even though they had never heard it before. As the words of the song rolled out of his mouth, they also came out of the children’s mouths! Somehow those little five-year-olds were able to instantaneously imitate both the words and the tune of the new song! Did they also understand the meaning of the words? Not necessarily. Just as reading comprehension does not automatically follow accurate decoding (reading a sentence aloud correctly, without understanding its meaning), the universal talent for linguistic mimicry and memorization does not always connect with the mental realm of curiosity, meaning, and understanding.

What do the stories of Jose, Robin, and the other students have in common? They were all skip-chanting, not skip-counting. Their words were mere regurgitations of memorized linguistic patterns—like Frère Jacques—not indicators of perceived amounts. They recalled them the same way that students recall the words to the Pledge to the Flag, through sheer rote memorization—just as I had memorized the nonsense syllables at my high school pep rally. But without an understanding of the concepts behind them, fluently recalled words do not provide a sure basis for developing mathematical understanding. Unfortunately, classrooms throughout the country regularly engage in whole-class unison skip-chanting. When all the students are saying the right words together, the teachers are too often satisfied with the deceptive evidence that learning has taken place—not realizing that if only one student in the class can count by fours, the rest of the class can simultaneously imitate the words, just as the kindergartners instantaneously mimicked the words of their new song.

However, rote memorization is only one of many kinds of memory. Just as there are many different learning styles or modalities, there are also many ways of developing memory. I have found that the model most applicable to the development of conceptually connected mathematical (not merely linguistic) memory is the way in which we learn our way around a new city. We do not use flash cards, timed tests, rhymes, tricks, and unison chanting to accomplish that task. Instead, we look at maps and travel repeatedly around the city, gradually building a mental map of landmarks, streets, and locations. And as we continue traveling to meaningful destinations, our need for maps and directions gradually diminishes until we know our way around with such familiarity that we can go where we want without even thinking about it.

This everyday approach to memory development is normally referred to as remembering—as opposed to memorizing. Even though they both have to do with memory, they are clearly not the same thing. Memorization is purely verbal, sometimes has no connection with experience or conceptual understanding, and is much more stressful. Remembering, on the other hand, is generally derived from multi-sensory kinesthetic experiences within a spatial/conceptual context, with a connected verbal component, and generates relatively little stress.

Here is an example of how to teach skip-counting by fives in a way which incorporates a mathematical way of remembering, rather than a linguistic way of memorizing. Present the students with their own copy of a vertical array of pea pods, with each pod containing five numbered peas.

[   (1)     (2)     (3)     (4)     (5)  ]

[   (6)     (7)     (8)     (9)    (10) ]

[  (11)   (12)   (13)   (14)   (15) ]


Giving very brief directives, accompanied by clarifying gestures…

• Have the pupils touch each pea and count them aloud in a quiet voice—except for the last pea on the right in each group, which should be counted in a loud voice:

“One, two, three, four, FIVE;

six, seven, eight, nine, TEN; etc.”

Watch the students carefully, and do not allow the class to go faster than the slowest student can manage.

If the speed accelerates to a pace comfortable only for the fastest students, the slower ones are likely to stop touching-and-counting, and will cope with the situation by reverting to rote verbal imitation of their peers.

When the special ed student mentioned above was given these directions, she followed them easily, then smiled and said “I get it!” It is important that the objects (the peas, in this case) in such an array be numbered; without that visual imprint, some students do not make the connection between the numbers that are saying aloud and the written numbers that teachers hope they are imagining (because they are not imaging them!).

• Next, have the students whisper the counting words as they touch the peas, saying each fifth number in a regular voice:

“One, two, three, four, five;

six, seven, eight, nine, ten; etc.”

When the girl mentioned above followed these directions, she laughed and said “This is easy! I can do it!”

• Then have the pupils touch-and-count the peas again, thinking the first four counting words as they touch the peas, and saying each fifth number in a regular voice:

“(One, two, three, four,) five;

(six, seven, eight, nine,) ten; etc.”

The girl’s reaction conveyed the pleasure engendered by understanding: “This is fun! I like learning this way!”

• Then have the pupils slide a finger across each group of peas, smoothly gliding from left to right as they again think the first four counting words, and say each fifth number in a regular voice:

“(One, two, three, four,) five;

(six, seven, eight, nine,) ten; etc.”

• Now present the students with another vertical array of pea pods, with each pod containing five unnumbered peas (see graphic above).

[   (  )     (  )     (  )     (  )     (  )  ]

[   (  )     (  )     (  )     (  )     (  )  ]

[   (  )     (  )     (  )     (  )     (  )  ]


Then have the pupils again slide a finger across each group of peas, as they think the first four counting words, and say each fifth number in a regular voice:

“(One, two, three, four,) five;

(six, seven, eight, nine,) ten; etc.”

The students are now skip-counting by fives. The same approach can be used to teach skip-counting by other numbers—only different graphics are required. Each child must be given the opportunity to show that they can do the last step (skip-counting groups of unnumberd objects) by themselves, without the possibility of verbally imitating other students. The first three steps should be reviewed (with teacher support) by students who display uncertainty, hesitation, or inaccuracy. (“You sound like you’re not certain about that. Count them for me again so we can see if you’re right.”)

What distinguishes skip-counting from skip-chanting? Skip-counting requires physical interaction with numbered objects; skip-chanting requires no actual counting at all. Skip-counting requires mathematical thinking; skip-chanting can be accomplished with no thinking whatsoever. Many teachers rely on slow-paced counting activities with physically constructed grouped amounts to develop the concept of skip-counting, but then revert to skip-chanting to develop fluent recall of the number-facts. They assume that since their students understood the conceptual part of the lesson, they will automatically invest the following rote verbal exercise with understanding. Experience shows that some students do make that connection. Other students, however, are not rapidly recalling the previously counted groups during the group chanting exercise; for them, skip-chanting is a near trance-like state with only one goal: successful verbal duplication. Verbal imitation does not require any conceptual connection in order to be successfully performed. For that reason, some students make the connection while others do not; during the same group activity, some students can be truly skip-counting, while others are merely skip-chanting. The pea-pod lesson modeled above provides all students with the means to remain conceptually connected during the memory-building phase of the skip-counting lesson.

Following on the previous two posts, here is the Partner or Folding Pages podcast. With the partner pages, students rediscover, reinforce, and extend the work they did on the graphic pages. They connect manipulation with computation and continue building memory by taking more spins around the city.

Four additional features of the partner pages that support students who are not doing well in math are:
1. They involve cooperative learning with individual accountability
2. Students receive immediate and ongoing feedback
3. They engage teacher, peers, and students in student self-correction
4. They use no-stress timing focused on improving rather than merely measuring performance (See the earlier postings on fluency for a discussion of this.)

Again, because of the lesson design, we can observe and assess how students are doing each step of the way – and make the adjustments our observations indicate.

Vodpod videos no longer available.

more about “Partner or Folding Pages“, posted with vodpod

We were asked if we could post the podcasts referred to in the previous assessment posting, so here is a slightly abbreviated version of the Soccer Teams podcast.

We began that posting noting the importance of designing materials that enable observation while accomplishing learning objectives. The Soccer Teams graphic page is a model of that.

1. It can be used to support students who are not succeeding with the regular text book.
2. It can be used up front to quickly orient students to a concept or procedure, increasing the likelihood that they will succeed with the regular curriculum.
3. It can also be used to efficiently cover prior skill gaps so that students are capable of handling the current lesson.

Students not doing well with multiplication or division may not understand what multiplication and division really mean. Then they try to memorize the things they don’t understand. Students can memorize, “quoth the raven…” Say it enough times and they can fill in the blank sounding like they really know something. But they may very well not know what “quoth” or “nevermore” mean or recognize a raven if they saw one.

With the Soccer Teams graphic, they are able to experience how a single group can be one and many (1 group of 11), and the feeling for magnitude between 1 x 11, 2 x 11,  7 x 11 or 12 x 11. These are some of the conceptual building blocks of multiplication. Times tables are not. By working with the graphic pages, students begin building a memory of these experiences the same way we remember our way around a new city. We don’t sit at home and memorize the streets with flash cards.  We may orient ourselves with a map, but then we go out and drive around. That’s how we learn the city.

With the graphic pages students drive around so we can observe and assess how they’re doing right from the beginning and each step of the way.

Vodpod videos no longer available.

more about “The Soccer Teams Graphic“, posted with vodpod

Standard timing practice has more to do with measurement than improvement. Measurement is useful, so is improvement. They can be accomplished together.

The standard approach to timing along with the fact that it is typically done without any graphic or manipulative support to refresh knowledge of the facts creates more problems then it solves.

Students write some incorrect answers, which can reinforce memories of wrong answers. Students leave answers blank, which does little for their interest in mathematics, reinforces a negative self-concept, and causes them to miss needed practice on certain problems. Getting the paper back sometime later when the students are no longer engaged in the exercise means they probably will not go over missed problems to see where they went wrong. When it is corrected by someone else and not self-corrected, they are another step removed from the whole process.

Again, measurement and improvement can be accomplished together. Consider the posting “Measuring AND Improving Fluency.”