Obrien FINAL Chapter 5 and chapter 6.ppt
MuhammadAdeel321
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Sep 18, 2024
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About This Presentation
Very Informative
Slide Content
Math/Science/Technology (MST) K-5
Teacher Preparation Program at TNCJ
Dr. Steve ODr. Steve O’’BrienBrien
Associate ProfessorAssociate Professor
Director, Center for Excellence in STEM EducationDirector, Center for Excellence in STEM Education
Dr. John KarsnitzDr. John Karsnitz
Professor and ChairProfessor and Chair
School of EngineeringSchool of Engineering
The College of New JerseyThe College of New Jersey1
Teacher Preparation Program at TNCJ
Dr. Steve ODr. Steve O’’BrienBrien
Associate ProfessorAssociate Professor
Director, Center for Excellence in STEM EducationDirector, Center for Excellence in STEM Education
Dr. John KarsnitzDr. John Karsnitz
Professor and ChairProfessor and Chair
School of EngineeringSchool of Engineering
The College of New JerseyThe College of New Jersey1
The College of New Jersey
•Primarily Undergraduate
•Schools
–Education, Engineering, Business, Nursing
–Science
–Arts & Comm., Humanities & Social Sci.
•~6000 Undergraduates
•95% On-Campus Freshman
•850 Graduate Students
•326 Faculty (12:1 Ratio)
•>50 Liberal Arts & Professional Programs
2
•Primarily Undergraduate
•Schools
–Education, Engineering, Business, Nursing
–Science
–Arts & Comm., Humanities & Social Sci.
•~6000 Undergraduates
•95% On-Campus Freshman
•850 Graduate Students
•326 Faculty (12:1 Ratio)
•>50 Liberal Arts & Professional Programs
2
TCNJ School of Engineering
K-12 13-16 16-20+
Biomedical
Civil
Computer
Electrical
Mechanical
Technology/
pre-engineering
education [K-12]
MST [K-5(8)]
MAT
Active UG Research
30% graduates go
onto graduate or
prof. school
Future Prof. Dev.
Opportunities
Supports K-20+ Engineering Education Pipeline
Ctr for Excel. In STEM Ed.
3
~50
160
10
K-12 13-16 16-20+
Biomedical
Civil
Computer
Electrical
Mechanical
Technology/
pre-engineering
education [K-12]
MST [K-5(8)]
MAT
Active UG Research
30% graduates go
onto graduate or
prof. school
Future Prof. Dev.
Opportunities
Supports K-20+ Engineering Education Pipeline
Ctr for Excel. In STEM Ed.
3
~50
160
10
MST Education Major
1)How would you define integrated STEM education?
2)Briefly describe history, content, and impact of the MST
program, citing data whenever possible.
1)Challenges in design and implementation has the MST
program faced, and how have these challenges been addressed?
2)Few of the most important unanswered questions regarding K-
12 teacher preparation to teach integrated STEM?
Questions asked by NAE/NRC:
4
1)How would you define integrated STEM education?
2)Briefly describe history, content, and impact of the MST
program, citing data whenever possible.
1)Challenges in design and implementation has the MST
program faced, and how have these challenges been addressed?
2)Few of the most important unanswered questions regarding K-
12 teacher preparation to teach integrated STEM?
Questions asked by NAE/NRC:
4
MST Education Major
1)How would you define integrated STEM education?
2)Briefly describe history, content, and impact of the MST
program, citing data whenever possible.
1)Challenges in design and implementation has the MST
program faced, and how have these challenges been addressed?
2)Few of the most important unanswered questions regarding K-
12 teacher preparation to teach integrated STEM?
Questions asked by NAE/NRC:
5
1)How would you define integrated STEM education?
2)Briefly describe history, content, and impact of the MST
program, citing data whenever possible.
1)Challenges in design and implementation has the MST
program faced, and how have these challenges been addressed?
2)Few of the most important unanswered questions regarding K-
12 teacher preparation to teach integrated STEM?
Questions asked by NAE/NRC:
5
i-STEM Definition / Thoughts
Very important to define i-STEM well
Many studies cite lowered National performance in M & S [T&E?]
Big impact on economic & social processes
“STEM” has become to mean S or T or E or M
Has lead to the acronym becoming less useful, perhaps harmful
Government officials: “ … more support for M & S”
Lose “interconnectedness”
Need a better acronym: “integrated-STEM” is a good step
Why?
SM ET
Separate silos with
perhaps M:S and T:E
6
Very important to define i-STEM well
Many studies cite lowered National performance in M & S [T&E?]
Big impact on economic & social processes
“STEM” has become to mean S or T or E or M
Has lead to the acronym becoming less useful, perhaps harmful
Government officials: “ … more support for M & S”
Lose “interconnectedness”
Need a better acronym: “integrated-STEM” is a good step
Why?
SM ET
Separate silos with
perhaps M:S and T:E
6
i-STEM Definition / Thoughts
Two (related) Reasons:
Multi/Inter-disciplinary education pedagogy
T&E is special, (i) motivator/connector (ii) problem-solving process
S
M
E
T
M&S
or … T
&
E
student
unknown/
abstract
*Dolan, R. J. (2002). Emotion, Cognition, and
Behavior. Science Vol. 298, Nov. 8, 2002.
network
7
Really highly
networked relationships
The students’ world is
strongly linked to the T&E
Two (related) Reasons:
Multi/Inter-disciplinary education pedagogy
T&E is special, (i) motivator/connector (ii) problem-solving process
S
M
E
T
M&S
or … T
&
E
student
unknown/
abstract
*Dolan, R. J. (2002). Emotion, Cognition, and
Behavior. Science Vol. 298, Nov. 8, 2002.
network
7
Really highly
networked relationships
The students’ world is
strongly linked to the T&E
i-STEM Definition
Possible Def’n: Integration of 2 or more of the 4 STEM
content area with each other into a teaching/learning
experience with purposeful intent of deepening learning.
Common Ex.: M + S
Does not include non-STEM integrations [Soc. St. + M, or … etc.]
Does not account for context/motivation capability of the T&E
Modified Def’n: Integration of 1 or more STEM contents into
A teaching/learning experience, with purposeful intent of
deepening learning.
Ex.’s: M + T/E, S + M, Soc. St. + T/E, or Lang. Arts + S
Due to context-setting and problem-solving process of T&E,
our preference is integrating T&E to other subjects. [Note: E
M&S]
8
Possible Def’n: Integration of 2 or more of the 4 STEM
content area with each other into a teaching/learning
experience with purposeful intent of deepening learning.
Common Ex.: M + S
Does not include non-STEM integrations [Soc. St. + M, or … etc.]
Does not account for context/motivation capability of the T&E
Modified Def’n: Integration of 1 or more STEM contents into
A teaching/learning experience, with purposeful intent of
deepening learning.
Ex.’s: M + T/E, S + M, Soc. St. + T/E, or Lang. Arts + S
Due to context-setting and problem-solving process of T&E,
our preference is integrating T&E to other subjects. [Note: E
M&S]
8
i-STEM & Prob. Based Learning
PBL is not i-STEM but is often a technique used in i-STEM
activities
9
PBL is not i-STEM but is often a technique used in i-STEM
activities
9
MST Education Major
1)How would you define integrated STEM education?
2)Briefly describe history, content, and impact of the MST
program, citing data whenever possible.
1)Challenges in design and implementation has the MST
program faced, and how have these challenges been addressed?
2)Few of the most important unanswered questions regarding K-
12 teacher preparation to teach integrated STEM?
Questions asked by NAE/NRC:
10
1)How would you define integrated STEM education?
2)Briefly describe history, content, and impact of the MST
program, citing data whenever possible.
1)Challenges in design and implementation has the MST
program faced, and how have these challenges been addressed?
2)Few of the most important unanswered questions regarding K-
12 teacher preparation to teach integrated STEM?
Questions asked by NAE/NRC:
10
The MST K-5(8) Program
Context / History
Goals
Program Description
Impacts
11
Context / History
Goals
Program Description
Impacts
11
History
Mid-1990’s: noticed that fewer & fewer K-5 teachers
had deep STEM training / experiences, especially T&E
As the cohorts
progressed, STEM
subjects lost
students
non-STEM subjects
gained substantial
number of students
12
Mid-1990’s: noticed that fewer & fewer K-5 teachers
had deep STEM training / experiences, especially T&E
As the cohorts
progressed, STEM
subjects lost
students
non-STEM subjects
gained substantial
number of students
12
History
Technology recognized as one of 13 General Ed goals
Society, Ethics, and Technology (1990).
New Jersey Systemic Statewide Initiative director (STEM)
Dr. J. Karsnitz (Chair) convenes study group (1995),
[School of Ed. and Arts & Sciences] ...
MST approved as a new major by TCNJ and NJ Higher
Education governance system (1998).
MST approved as academic major by NJ DOE (2000).
13
Technology recognized as one of 13 General Ed goals
Society, Ethics, and Technology (1990).
New Jersey Systemic Statewide Initiative director (STEM)
Dr. J. Karsnitz (Chair) convenes study group (1995),
[School of Ed. and Arts & Sciences] ...
MST approved as a new major by TCNJ and NJ Higher
Education governance system (1998).
MST approved as academic major by NJ DOE (2000).
13
Bring more STEM / i-STEM trained teachers into the
elementary classroom
goal 50% of TCNJ K-5 grads
Expose elementary children to the significance of T&E
Use T&E to increase learning effectiveness in K-5(8)
MST Program Goals
14
elementary classroom
goal 50% of TCNJ K-5 grads
Expose elementary children to the significance of T&E
Use T&E to increase learning effectiveness in K-5(8)
MST Program Goals
14
Education Majors in NJ
a)Elementary Education,
b)Early Childhood Education
c)Special Education &
d)Deaf & Hard of Hearing
e)Urban Ed.
1)Must have a Disciplinary Major
2)Must have an Education “dual” major
K-5:
English, Sociology, Art,
Music, History, Psych.,
Spanish, WGS,
Math, Bio., MST
Disciplinary Major Education Dual Major
Secondary (examples):
a)MS/HS Physics: Secondary + Physics
b)MS/HS Math: Secondary + Math
c)MS/HS English: Secondary + Physics
… etc.
15
a)Elementary Education,
b)Early Childhood Education
c)Special Education &
d)Deaf & Hard of Hearing
e)Urban Ed.
1)Must have a Disciplinary Major
2)Must have an Education “dual” major
K-5:
English, Sociology, Art,
Music, History, Psych.,
Spanish, WGS,
Math, Bio., MST
Disciplinary Major Education Dual Major
Secondary (examples):
a)MS/HS Physics: Secondary + Physics
b)MS/HS Math: Secondary + Math
c)MS/HS English: Secondary + Physics
… etc.
15
MST Program Structure (32 Units)
8 Units Liberal Learning
A&H, SS/History, Natural Science
& Quantitative Reasoning
12 Units Major
- Core (+M/S from LL) and
- Specialization (required “minor”)
12 Units Professional
Education (starting ~Soph. Year)
1 Unit = 4 credits 16
8 Units Liberal Learning
A&H, SS/History, Natural Science
& Quantitative Reasoning
12 Units Major
- Core (+M/S from LL) and
- Specialization (required “minor”)
12 Units Professional
Education (starting ~Soph. Year)
1 Unit = 4 credits 16
MST Major Courses
CORE** – 8 units
Mathematics – 1 units
Technology – 2 units
Science – 2 units
MST Electives (M or S or T&E) – 2 units
i-STEM [TED460] – 1 unit
SPECIALIZATION (“Minor”) – 4 units
M, S or T (equal to a minor in discipline)
1 Unit = 4 credits
**Creative Design &
Calculus-I are contained
in Liberal Learning
17
CORE** – 8 units
Mathematics – 1 units
Technology – 2 units
Science – 2 units
MST Electives (M or S or T&E) – 2 units
i-STEM [TED460] – 1 unit
SPECIALIZATION (“Minor”) – 4 units
M, S or T (equal to a minor in discipline)
1 Unit = 4 credits
**Creative Design &
Calculus-I are contained
in Liberal Learning
17
Specializations
~100% of graduates satisfy requirements for Middle School
endorsements in M or S. [4 courses in M or S … etc.]
A large majority (70-90%) satisfy requirements for Middle School
endorsements in both M or S [4 courses in both M & S … etc.]
~40% of graduates satisfy requirements for K-12 Technology
Education endorsement
1)Technology
2)Mathematics
3)Science (Bio, Chemistry or Physics)
For a total of 5 possible specializations
18
~100% of graduates satisfy requirements for Middle School
endorsements in M or S. [4 courses in M or S … etc.]
A large majority (70-90%) satisfy requirements for Middle School
endorsements in both M or S [4 courses in both M & S … etc.]
~40% of graduates satisfy requirements for K-12 Technology
Education endorsement
1)Technology
2)Mathematics
3)Science (Bio, Chemistry or Physics)
For a total of 5 possible specializations
18
•Calculus-I*
•MAT105* Mathematical Structures & Algorithms for Educators-I
•MTT202* Teaching Mathematics in the Early Childhood & Elementary
Classroom {Methodology / Pedagogy}
•Engineering (applied) Math
[~85% take this and will likely become required]
•MAT106 Mathematical Structures & Algorithms for Educators-II
•Calc-II
•STA115/215
Required / Typical Math Courses
* Required
19
•MAT105* Mathematical Structures & Algorithms for Educators-I
•MTT202* Teaching Mathematics in the Early Childhood & Elementary
Classroom {Methodology / Pedagogy}
•Engineering (applied) Math
[~85% take this and will likely become required]
•MAT106 Mathematical Structures & Algorithms for Educators-II
•Calc-II
•STA115/215
Required / Typical Math Courses
* Required
19
•MST202* Methods of Teaching Science, Health and
Technology
•SCI103 Physical, Earth, and Space Sciences
•SCI104 Genes, Cancer and the Environment
•PHY120 Introduction to Geology
•PHY161 Introduction to Astronomy
•PHY171 Introduction to Meteorology
Typical Sci. Courses
No specific Science Content courses are required
EXCEPT for Science Specialization MST [Bio., Physics, Chemistry]
* Required
20
Technology
•SCI103 Physical, Earth, and Space Sciences
•SCI104 Genes, Cancer and the Environment
•PHY120 Introduction to Geology
•PHY161 Introduction to Astronomy
•PHY171 Introduction to Meteorology
Typical Sci. Courses
No specific Science Content courses are required
EXCEPT for Science Specialization MST [Bio., Physics, Chemistry]
* Required
20
T&E Courses
All T&E Courses part of existing Secondary TechEd/PreEng Program
2005: Major curriculum change
TechEd TechEd/Pre-Eng
(i) More M & S and (ii) Hired Professors w/ Eng. degrees
Unlike M & S courses, the “content” T&E courses also contain
substantial Pedagogy/methods (all students are Education)
21
All T&E Courses part of existing Secondary TechEd/PreEng Program
2005: Major curriculum change
TechEd TechEd/Pre-Eng
(i) More M & S and (ii) Hired Professors w/ Eng. degrees
Unlike M & S courses, the “content” T&E courses also contain
substantial Pedagogy/methods (all students are Education)
21
•Creative Design*
•Multimedia Design (2D)*
•Structures & Mechanisms*
•Integrated-STEM for Child/Adoles. Learner* {Method. / Pedagogy}
•Engineering (applied) Math
[~85% take this and will likely become required]
•BioTech
•Facilities
•Arch. & Civil
Required / Typical T&E Courses
* Required
22
•Multimedia Design (2D)*
•Structures & Mechanisms*
•Integrated-STEM for Child/Adoles. Learner* {Method. / Pedagogy}
•Engineering (applied) Math
[~85% take this and will likely become required]
•BioTech
•Facilities
•Arch. & Civil
Required / Typical T&E Courses
* Required
22
Teaching as a Design Process*
Young ages:
Key for setting STEM affect / self-efficacy
Capable age group [Age-appropriate bias]
Girls & minorities
Dev. a deeper understanding of i-STEM and be able to
defend it
Research in field
Plan and implement i-STEM lessons [Purposeful intent]
Physical nature of learning environment
Integrating T&E into K-5
i-STEM Course Overview
23
*Hiebert, J. et. al: Preparing teachers to learn from teaching [J. Teacher Ed. (2007)] and
Learning to learn to teach an “experimental” model for teaching and teacher preparation in
mathematics [J. of Mathematics Teacher Ed. (2003)]
Young ages:
Key for setting STEM affect / self-efficacy
Capable age group [Age-appropriate bias]
Girls & minorities
Dev. a deeper understanding of i-STEM and be able to
defend it
Research in field
Plan and implement i-STEM lessons [Purposeful intent]
Physical nature of learning environment
Integrating T&E into K-5
i-STEM Course Overview
23
*Hiebert, J. et. al: Preparing teachers to learn from teaching [J. Teacher Ed. (2007)] and
Learning to learn to teach an “experimental” model for teaching and teacher preparation in
mathematics [J. of Mathematics Teacher Ed. (2003)]
•In vibrant School of Engineering
•Stay Current (pre-engineering, textbooks . . . etc.)
•STEM Center (Outreach and Research; staff of ~5)
•TSA-NJ Competition (>1600 HS and MS attendees)
•Professional Conference (21
st
annual, 1-day & ~8 sessions)
•Professional Workshop Series (~6 per year)
•TECA Competitions (Annually; compete & organize …)
•FIRST Robotics:
–Hosted state competition (~700 attendees)
–Hosted Workshops (training for new – old teams)
•Active Student society (TES)
•NJTEEA; very active
Programs not “in a vacuum”
… substantial informal learning
24
•Stay Current (pre-engineering, textbooks . . . etc.)
•STEM Center (Outreach and Research; staff of ~5)
•TSA-NJ Competition (>1600 HS and MS attendees)
•Professional Conference (21
st
annual, 1-day & ~8 sessions)
•Professional Workshop Series (~6 per year)
•TECA Competitions (Annually; compete & organize …)
•FIRST Robotics:
–Hosted state competition (~700 attendees)
–Hosted Workshops (training for new – old teams)
•Active Student society (TES)
•NJTEEA; very active
Programs not “in a vacuum”
… substantial informal learning
24
Impacts of the MST Program
Growth in K-5 STEM (i-STEM) grads
STEM & non-STEM content knowledge
Math Anxiety and Math teaching Self-efficacy
Gender
Anecdotal:
Job Placement
Curriculum dev. in teaching experiences
25
Growth in K-5 STEM (i-STEM) grads
STEM & non-STEM content knowledge
Math Anxiety and Math teaching Self-efficacy
Gender
Anecdotal:
Job Placement
Curriculum dev. in teaching experiences
25
High Growth of MST Program
STEM total: ~10%
& no T&E
STEM total: ~33%
Dominated by MST
(w/ T&E)
>200 graduates
Dept. Limit
Largest
K-5 major
26
STEM total: ~10%
& no T&E
STEM total: ~33%
Dominated by MST
(w/ T&E)
>200 graduates
Dept. Limit
Largest
K-5 major
26
Content Knowledge- M & S
ETS Praxis
TM
test #0014
Relative results by subscore subject
t-test results: [95% Conf.; N
MST=59, N
non-MST=346]
•Math: p = 0.004; Science: p = 0.001
(Example: for math the MST population scored 5.5%
higher than the non-MST population.)
MST graduates relative to non-MST graduates.
Statistically significant higher
M & S performance
Statistically equivalent
performance on non-STEM
subjects !
27
ETS Praxis
TM
test #0014
Relative results by subscore subject
t-test results: [95% Conf.; N
MST=59, N
non-MST=346]
•Math: p = 0.004; Science: p = 0.001
(Example: for math the MST population scored 5.5%
higher than the non-MST population.)
MST graduates relative to non-MST graduates.
Statistically significant higher
M & S performance
Statistically equivalent
performance on non-STEM
subjects !
27
Content Knowledge- T&E
Mapped TCNJ Curriculum onto Std. for Tech. Literacy (STL)
T&E content varies with Specialization
T specialization: T&E Coverage is very high, 90-100% for K-5
M & S specialization: T&E Coverage is high, 80-95% for K-5
Also, grades & Tech. Ed. Praxis data indicate
strong T&E content knowledge
28
Mapped TCNJ Curriculum onto Std. for Tech. Literacy (STL)
T&E content varies with Specialization
T specialization: T&E Coverage is very high, 90-100% for K-5
M & S specialization: T&E Coverage is high, 80-95% for K-5
Also, grades & Tech. Ed. Praxis data indicate
strong T&E content knowledge
28
Math Anxiety
shown relative to Math K-5 major population
--> i.e.- “+40%:” 40% higher than ave. K-5 math majors
p (MAT:MST) =
0.195
p (pre105-->
pos202) < 0.008 for
PSY, SO/WG &
MST
MAT105 MTT202
Pre Post Pre
MST Population shows dramatic drops in Math Anxiety
Post
29
1000 measures
~250 students
Math & MST: same (low)
anxiety after 2
nd
measure
shown relative to Math K-5 major population
--> i.e.- “+40%:” 40% higher than ave. K-5 math majors
p (MAT:MST) =
0.195
p (pre105-->
pos202) < 0.008 for
PSY, SO/WG &
MST
MAT105 MTT202
Pre Post Pre
MST Population shows dramatic drops in Math Anxiety
Post
29
1000 measures
~250 students
Math & MST: same (low)
anxiety after 2
nd
measure
Math Anxiety
Non-STEM vs. STEM
High anxiety (top quartile)
1:3
1:5
1:4
1:14
SAT (Math) Scores
TCNJ
Non-STEM [602]
MST [643]
K-5 Math [638]
- - - - - - - - - - - - -
National Ave.
Sch. of Ed. [483]
Sch. of Engin. [579]
Math [614]
30
Non-STEM vs. STEM
High anxiety (top quartile)
1:3
1:5
1:4
1:14
SAT (Math) Scores
TCNJ
Non-STEM [602]
MST [643]
K-5 Math [638]
- - - - - - - - - - - - -
National Ave.
Sch. of Ed. [483]
Sch. of Engin. [579]
Math [614]
30
Math Anxiety [MST Spec.’n]
RMANX: MST (Po202) RMANX: Tech. Spec.
N Ave SD N Ave SD
T&E 21 64.6 10.3 Pr105 11 76.8 15.9
Math 21 69.3 15.7 Po105 10 71 13.6
Sci 8 73.5 15.1 Pr202 18 67.2 8
Po202 21 64.6 10.3
Effects of T&E curriculum ?
Anxiety for T&E Special.z’n subpopulation drops dramatically
T&E has less M & S but more T&E courses
Substantial context, applications (applied math)
I II
Continuing Data Collection:
Double #’s within 1 year.
31
RMANX: MST (Po202) RMANX: Tech. Spec.
N Ave SD N Ave SD
T&E 21 64.6 10.3 Pr105 11 76.8 15.9
Math 21 69.3 15.7 Po105 10 71 13.6
Sci 8 73.5 15.1 Pr202 18 67.2 8
Po202 21 64.6 10.3
Effects of T&E curriculum ?
Anxiety for T&E Special.z’n subpopulation drops dramatically
T&E has less M & S but more T&E courses
Substantial context, applications (applied math)
I II
Continuing Data Collection:
Double #’s within 1 year.
31
Gender Benefits
Historically, a high level of MST graduates are male [15-20% ]
•TCNJ K-5 average is ~5%, independent of major
•National average for K-5 teachers is ~9% (2001) {1981: 18%}
80+% MST graduates are female
Research strongly indicates these graduates will be
effective role models for female K-5(8) students,
halting the gender “gap” in STEM
Continue?? 32
F
e
m
a
le
M
a
le
!!
Historically, a high level of MST graduates are male [15-20% ]
•TCNJ K-5 average is ~5%, independent of major
•National average for K-5 teachers is ~9% (2001) {1981: 18%}
80+% MST graduates are female
Research strongly indicates these graduates will be
effective role models for female K-5(8) students,
halting the gender “gap” in STEM
Continue?? 32
F
e
m
a
le
M
a
le
!!
Anecdotal Evidence
Job Placement
Historically, high job placement in ALL School of Ed., 90+%
MST grads had ~100% placement ... Until economy hit NJ-
education 2010/2011
2011 MST grads had tougher time. Placement is 70-80%
but almost ALL MST had call-backs and interviews.
Non-STEM majors seemed to have few “bites”
Some Districts specifically look for MST …
i-STEM Unit/Curriculum dev.
For both Jr. Experiences and Full-time Student Teaching,
students are developing high quality i-STEM, even in
schools where “science” is not policy.
Same for post-grad: New elective courses offered, …
requiring 4 new Sections … etc.
33
Job Placement
Historically, high job placement in ALL School of Ed., 90+%
MST grads had ~100% placement ... Until economy hit NJ-
education 2010/2011
2011 MST grads had tougher time. Placement is 70-80%
but almost ALL MST had call-backs and interviews.
Non-STEM majors seemed to have few “bites”
Some Districts specifically look for MST …
i-STEM Unit/Curriculum dev.
For both Jr. Experiences and Full-time Student Teaching,
students are developing high quality i-STEM, even in
schools where “science” is not policy.
Same for post-grad: New elective courses offered, …
requiring 4 new Sections … etc.
33
Overall Lessons Learned
“Teachers as Designers:” good Teach. Prep. Model
Design Process applies to T&L environment …
ID Problem Ideate . . . Assess … Loop
Mixing Elementary with Secondary students, all in the
School of Eng., are really good
T&E courses having Content & Pedagogy is good
Gender benefits:
STEM-capable female teachers [Big !]
Perhaps attract more male K-5 teachers
Math/Quant. literacy is a problem
T&E content likely helping math / science anxiety.
34
“Teachers as Designers:” good Teach. Prep. Model
Design Process applies to T&L environment …
ID Problem Ideate . . . Assess … Loop
Mixing Elementary with Secondary students, all in the
School of Eng., are really good
T&E courses having Content & Pedagogy is good
Gender benefits:
STEM-capable female teachers [Big !]
Perhaps attract more male K-5 teachers
Math/Quant. literacy is a problem
T&E content likely helping math / science anxiety.
34
Key Courses
TCNJ’s MST program has a lot of T&E, S & M
Institutions could not implement all of this content
What courses then do we think are “Central?”
Integrated-STEM for Child/Adoles. Learners
Creative Design
Applied / Eng. Math
Structures and Mechanisms
Combine
into 2
courses??
35
(1)Integrate a subset of these courses for non-STEM majors at TNCJ ?
(2)Studies underway for three of these courses (anxiety and affect)
TCNJ’s MST program has a lot of T&E, S & M
Institutions could not implement all of this content
What courses then do we think are “Central?”
Integrated-STEM for Child/Adoles. Learners
Creative Design
Applied / Eng. Math
Structures and Mechanisms
Combine
into 2
courses??
35
(1)Integrate a subset of these courses for non-STEM majors at TNCJ ?
(2)Studies underway for three of these courses (anxiety and affect)
MST Education Major
1)How would you define integrated STEM education?
2)Briefly describe history, content, and impact of the M/S/T
program, citing data whenever possible.
1)Challenges in design and implementation has the M/S/T
program faced, and how have these challenges been addressed?
2)Few of the most important unanswered questions regarding K-
12 teacher preparation to teach integrated STEM?
Questions asked by NAE/NRC:
36
1)How would you define integrated STEM education?
2)Briefly describe history, content, and impact of the M/S/T
program, citing data whenever possible.
1)Challenges in design and implementation has the M/S/T
program faced, and how have these challenges been addressed?
2)Few of the most important unanswered questions regarding K-
12 teacher preparation to teach integrated STEM?
Questions asked by NAE/NRC:
36
Enablers and Challenges
1)NJ State policy for requiring Disciplinary Major
2)Strong Culture / Respect for Design & Technology on campus
3)Chair was respected leader / communicator across campus
4)Had T&E course framework & General M & S
Enablers for establishing MST @ TCNJ
1)Depth vs. Breadth
M & S initially wanted substantial depth in their fields
Led to a frank discussion that one can’t have both breadth and
depth in a multidisciplinary program Specialization
Requirement
2)Attracting students: Marketing
3)Ongoing / current challenges (post-establishment)
Challenges for establishing MST @ TCNJ
37
1)NJ State policy for requiring Disciplinary Major
2)Strong Culture / Respect for Design & Technology on campus
3)Chair was respected leader / communicator across campus
4)Had T&E course framework & General M & S
Enablers for establishing MST @ TCNJ
1)Depth vs. Breadth
M & S initially wanted substantial depth in their fields
Led to a frank discussion that one can’t have both breadth and
depth in a multidisciplinary program Specialization
Requirement
2)Attracting students: Marketing
3)Ongoing / current challenges (post-establishment)
Challenges for establishing MST @ TCNJ
37
Enablers and Challenges for
other Schools
~5 Universities have inquired about our i-STEM program as part of their
effort to establish i-STEM in their K-5
Obstacles:
Entrenched & “packed” K-5 programs / Faculty Loading / Economy
No Stds/State Policies for T&E or i-STEM in K-5 (or even 6-12)
PA: (i) K-5 K-2 & 3-8, (ii) Increase in field experience time
MD: Counterpoint, Strong State-wide Effort in i-STEM
[Stds, Teacher Prep, Assessment … etc.]
CN: perhaps a strong Govern.-driven effort starting … ?
Leaders / Visionaries in K-5 Faculty / Chairs
38
other Schools
~5 Universities have inquired about our i-STEM program as part of their
effort to establish i-STEM in their K-5
Obstacles:
Entrenched & “packed” K-5 programs / Faculty Loading / Economy
No Stds/State Policies for T&E or i-STEM in K-5 (or even 6-12)
PA: (i) K-5 K-2 & 3-8, (ii) Increase in field experience time
MD: Counterpoint, Strong State-wide Effort in i-STEM
[Stds, Teacher Prep, Assessment … etc.]
CN: perhaps a strong Govern.-driven effort starting … ?
Leaders / Visionaries in K-5 Faculty / Chairs
38
MST Education Major
1)How would you define integrated STEM education?
2)Briefly describe history, content, and impact of the M/S/T
program, citing data whenever possible.
1)Challenges in design and implementation has the M/S/T
program faced, and how have these challenges been addressed?
2)Few of the most important unanswered questions regarding K-
12 teacher preparation to teach integrated STEM?
Questions asked by NAE/NRC:
39
1)How would you define integrated STEM education?
2)Briefly describe history, content, and impact of the M/S/T
program, citing data whenever possible.
1)Challenges in design and implementation has the M/S/T
program faced, and how have these challenges been addressed?
2)Few of the most important unanswered questions regarding K-
12 teacher preparation to teach integrated STEM?
Questions asked by NAE/NRC:
39
Important Questions
–Affect
–Anxiety/S. Eff.
–Content
–Problem-solving/
21
st
-Cent. skills
Students
–Affect
–Anxiety/S. Eff.
–Content/Methods
–Problem-solving/
21
st
-Cent. skills
Teachers
–Impact others?
[Teachers, Admin.,
Policy, State … ]
–i-STEM Curr. Dev.?
–Expanding i-STEM
activities/methods?
T&L
Environ.
Perhaps 3 categories of important research questions:
Teacher Prep
Long- and short-term Impacts, not simply Pre vs. Post
PBL is our ally and challenge here
[i-STEM approaches vs. Conventional]
40
–Affect
–Anxiety/S. Eff.
–Content
–Problem-solving/
21
st
-Cent. skills
Students
–Affect
–Anxiety/S. Eff.
–Content/Methods
–Problem-solving/
21
st
-Cent. skills
Teachers
–Impact others?
[Teachers, Admin.,
Policy, State … ]
–i-STEM Curr. Dev.?
–Expanding i-STEM
activities/methods?
T&L
Environ.
Perhaps 3 categories of important research questions:
Teacher Prep
Long- and short-term Impacts, not simply Pre vs. Post
PBL is our ally and challenge here
[i-STEM approaches vs. Conventional]
40
Questions for Teacher Prep
What aspects of i-STEM are needed / preferred in (i) K-
5(8) and (ii) Teacher Prep.?
T&E (i-STEM content/benefits)
PBL
Pre- vs. in-service
Systemic change vs. speed
How to promote both?
In-service data promote systemic change
Committee could also refer to output from ASEE’s
Workshop on Eng. Ed. in K-5 (@NCSU) [2009]
41
What aspects of i-STEM are needed / preferred in (i) K-
5(8) and (ii) Teacher Prep.?
T&E (i-STEM content/benefits)
PBL
Pre- vs. in-service
Systemic change vs. speed
How to promote both?
In-service data promote systemic change
Committee could also refer to output from ASEE’s
Workshop on Eng. Ed. in K-5 (@NCSU) [2009]
41
Foundation Funded i-STEM …
Acquired Foundation Funding to promote i-STEM
curriculum [$100K Year-1, building over successive years]
New NJ standards on 21
st
Century skills
New NJ policy on Prof. Learning Communities
PD i-STEM w/ EbD
TM
curriculum
oEbD is inexpensive and very flexible
o EbD onlline enables large data collection
Key Goals:
Successful PD for i-STEM curriculum (w/ EbD & TCNJ data
collection)
o20 Districts in Year-1
Pursue a few research questions (per previous slides)
Have PD become financially self-sustaining
Common curriculum / common dialog
42
Acquired Foundation Funding to promote i-STEM
curriculum [$100K Year-1, building over successive years]
New NJ standards on 21
st
Century skills
New NJ policy on Prof. Learning Communities
PD i-STEM w/ EbD
TM
curriculum
oEbD is inexpensive and very flexible
o EbD onlline enables large data collection
Key Goals:
Successful PD for i-STEM curriculum (w/ EbD & TCNJ data
collection)
o20 Districts in Year-1
Pursue a few research questions (per previous slides)
Have PD become financially self-sustaining
Common curriculum / common dialog
42
Thank you for your time !
•Dr. Steve O’Brien
Armstrong Hall 181
(609) 771-2780
[email protected]
•http://www.tcnj.edu/~tstudies
Questions:
43
•Dr. Steve O’Brien
Armstrong Hall 181
(609) 771-2780
[email protected]
•http://www.tcnj.edu/~tstudies
Questions:
43
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