Metacognition has two interacting phenomena guided by a person's cognitive regulation: •
Metacognitive knowledge (also called metacognitive awareness) is what individuals know about themselves and others like beliefs about thinking and such, as cognitive processors. •
Metacognitive experiences are those experiences that have something to do with the current, on-going cognitive endeavor. Metacognition refers to a level of thinking and metacognitive regulation, the regulation of cognition and subsequent learning experiences that help people enhance their learning through a set of activities. It involves active metacognitive control or attention over the process in learning situations. The skills that aid in regulation involve planning the way to approach a learning task, monitoring comprehension, and evaluating progress towards the completion of a task. Metacognition includes at least three different types of metacognitive awareness when considering metacognitive knowledge: •
Declarative knowledge: refers to knowledge about oneself as a learner and about what factors can influence one's performance. •
Procedural knowledge: refers to knowledge about doing things. This type of knowledge is displayed as heuristics and strategies. •
Conditional knowledge: refers to knowing when and why to use declarative and procedural knowledge. It allows students to allocate their resources when using strategies. This in turn allows the strategies to become more effective. These types of metacognitive knowledge also include: • Content knowledge (declarative knowledge), which involves understanding of one's own capabilities, such as a student evaluating their own knowledge of a subject in a class. It is notable that not all metacognition is accurate. Studies have shown that students often mistake lack of effort with understanding in evaluating themselves and their overall knowledge of a concept. Also, greater confidence in having performed well is associated with less accurate metacognitive judgment of the performance. • Task knowledge (procedural knowledge), which is how one perceives the difficulty of a task which is the content, length, and the type of assignment. The study mentioned in Content knowledge also deals with a person's ability to evaluate the difficulty of a task related to their overall performance on the task. Again, the accuracy of this knowledge was skewed as students who thought their way was better/easier also seemed to perform worse on evaluations, while students who were rigorously and continually evaluated reported to not be as confident but still did better on initial evaluations. • Strategic knowledge (conditional knowledge) is one's own capability for using strategies to learn information. Young children are not particularly good at this; it is not until students are in upper elementary school that they begin to develop an understanding of effective strategies. In short, strategic knowledge involves knowing
what (factual or declarative knowledge), knowing
when and why (conditional or contextual knowledge) and knowing
how (procedural or methodological knowledge). Similar to metacognitive knowledge, metacognitive regulation or "regulation of cognition" contains three skills that are essential. •
Planning: refers to the appropriate selection of strategies and the correct allocation of resources that affect task performance. •
Monitoring: refers to one's awareness of comprehension and task performance •
Evaluating: refers to appraising the final product of a task and the efficiency at which the task was performed. This can include re-evaluating strategies that were used. Metacognitive control is an important skill in cognitive regulation, it is about focusing cognitive resources on relevant information. Similarly, maintaining motivation to see a task to completion is also a metacognitive skill that is closely associated with the
attentional control. The ability to become aware of distracting stimuli – both internal and external – and sustain effort over time also involves metacognitive or
executive functions. Swanson (1990) found that metacognitive knowledge can compensate for IQ and lack of prior knowledge when comparing fifth and sixth grade students' problem solving. Students with a better metacognition were reported to have used fewer strategies, but solved problems more effectively than students with poor metacognition, regardless of IQ or prior knowledge. A lack of awareness of one's own knowledge, thoughts, feelings, and adaptive strategies leads to inefficient control over them. Hence, metacognition is a necessary life skill that needs nurturing to improve one's quality of life. Maladaptive use of metacognitive skills in response to stress can strengthen negative psychological states and social responses, potentially leading to psychosocial dysfunction. Examples of maladaptive metacognitive skills include worry based on inaccurate cognitive conceptions, rumination, and hypervigilance. Continuous cycles of negative cognitive conceptions and the associated emotional burden often lead to negative coping strategies such as avoidance and suppression. These can foster pervasive
learned helplessness and impair the formation of executive functions, negatively affecting an individual's quality of life. The theory of metacognition plays a critical role in successful learning, and it is important for both students and teachers to demonstrate understanding of it. Students who underwent metacognitive training including pretesting, self evaluation, and creating study plans performed better on exams. They are self-regulated learners who utilize the "right tool for the job" and modify learning strategies and skills based on their awareness of effectiveness. Individuals with a high level of metacognitive knowledge and skill identify blocks to learning as early as possible and change "tools" or strategies to ensure goal attainment. A broader repertoire of "tools" also assists in goal attainment. When "tools" are general, generic, and context independent, they are more likely to be useful in different types of learning needs. In one study examining students who received text messages during college lectures, it was suggested that students with higher metacognitive self-regulation were less likely than other students to have their learning affected by keeping mobile phones switched on in classes. Finally, there is no distinction between domain-general and domain-specific metacognitive skills. This means that metacognitive skills are domain-general in nature and there are no specific skills for certain subject areas. The metacognitive skills that are used to review an essay are the same as those that are used to verify an answer to a math question. However, whether metacognition is domain-general or domain-specific remains an active area of research. Neuroimaging and lesion studies have identified distinct neural substrates for perceptual versus memory metacognition, with perceptual judgments relying on anterior prefrontal cortex and memory monitoring engaging precuneus and medial parietal regions. A meta-analysis found no correlation between metacognition for perception and memory. However, domain-general confidence signals also exist in frontal and posterior midline regions, and large-scale behavioral studies report cross-domain correlations explaining approximately 15-20% of shared variance. This dissociation is particularly evident in aging, where older adults often retain metacognitive accuracy for memory while showing declines in perceptual metacognition, a pattern supported by distinct neural oscillatory mechanisms, including theta synchronization for perceptual metacognition and alpha desynchronization for memory metacognition.
Related concepts A number of theorists have proposed a common mechanism behind
theory of mind, the ability to model and understand the mental states of others, and metacognition, which involves a theory of one's own mind's function. Direct evidence for this link is limited. Several researchers have related
mindfulness to metacognition. Mindfulness includes at least two mental processes: a stream of mental events and a higher level awareness of the flow of events.
Measuring metacognition Research on metacognition has distinguished between metacognitive bias, metacognitive sensitivity, and metacognitive efficiency. Metacognitive bias refers to a general tendency toward overconfidence or underconfidence in judgments about one's performance. Metacognitive sensitivity describes how well confidence judgments distinguish between correct and incorrect responses. Metacognitive efficiency refers to a subject’s level of metacognitive sensitivity relative to task performance and allows researchers to assess how effectively individuals evaluate their own performance independent of overall accuracy. Traditional measures of metacognition include confidence ratings following a decision or response, judgments of learning, and feeling-of-knowing judgments. However, such measures can be influenced by response biases and other factors unrelated to metacognitive ability. To address this issue, formal measures based on signal detection theory have been developed. These approaches use techniques such as receiver operating characteristic (ROC) analysis and metrics such as meta-d′ to estimate how effectively confidence judgments discriminate between correct and incorrect responses. == Social metacognition ==