and Data Transmission Phase 5: Evaluation and Analysis of the Entire System NOTE: The content of the Phases on this table above are here in the figure below PHASE 2: Sensor System Development PHASE 1: Data Collection 1. Optimize Arduino/ADXL for low-frequency earthquake detection. 2. Design a network for direct seismic data transmission. 3. Study how does the GSM module will send to a user without interruption. 4. Test the accuracy receive of the ADXL Accelerometer for each vibration. 5. Examine measures analyzing ground motion as it happens. 6. Build the circuit of the sensors and the real-time to detect seismic activity that provides alert to the Arduino. 7. Make a program code on the Arduino that will convert the readings and send to a user. 17. identify areas for improvement based on the evaluation results and optimize the system design, algorithms, and components to enhance accuracy, reliability, and efficiency PHASE 3: System integration and Alert Mechanism Development 16. Evaluate system performance and reliability in real earthquakes via field tests, considering diverse intensities, frequencies, and environmental factors. 8. Develop a robust alert module that integrates with the Arduino Mega 2560 seismic sensor system. 9. Integrate a buzzer for audible earthquake alerts when ground motion exceeds a threshold. 10. Assess alert module efficacy and responsiveness for guaranteed timely and accurate warnings. PHASE S: Evaluation and Analysis of the Entire System 15. Validate system's seismic wave energy calculation and classification for both geological and human activities. PHASE 4: Wireless Communication and Data Transmission 11. Develop a wireless communication protocol to facilitate the direct transmission of seismic data from the Arduino Mega 2560 system to a designated receiver or server. 12.Analyze wireless system's speed, reliability, and data integrity for seismic transmission, factoring in distance, interference, and data security. 13. Enhance data transmission efficiency for seismic data through error correction, compression, and optimized protocols. 14. Evaluate the efficiency of data transmission to the server, considering factors such as speed, reliability, and consistency.

Understanding Business
12th Edition
ISBN:9781259929434
Author:William Nickels
Publisher:William Nickels
Chapter1: Taking Risks And Making Profits Within The Dynamic Business Environment
Section: Chapter Questions
Problem 1CE
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Question

Fill the Table of Matrix of Methodology

NOTE: The content of Phases in the Matrix of Methodology is provided below in the table in the picture and must be based on how to make the following phases for Research Setting, Respondents, Data Gathering Procedure, Data Gathering Instruments, and Statistical Treatment. 

PHASE 1:
Data Collection
1. Optimize Arduino/ADXL
for low-frequency
earthquake detection.
2. Design a network for
direct seismic data
transmission.
3. Study how does the
GSM module will send to
a user without
interruption.
PHASE 2:
Sensor System
Development
4. Test the accuracy receive of
the ADXL Accelerometer for
each vibration.
5. Examine measures analyzing
ground motion as it happens.
6. Build the circuit of the
sensors and the real-time to
detect seismic activity that
provides alert to the Arduino.
7. Make a program code on the
Arduino that will convert the
readings and send to a user.
17. Identify areas for improvement
based on the evaluation results and
optimize the system design,
algorithms, and components to
enhance accuracy, reliability, and
efficiency.
PHASE 3:
System Integration and
Alert Mechanism
Development
16. Evaluate system performance
and reliability in real
earthquakes via field tests,
considering diverse intensities,
frequencies, and environmental
factors.
8. Develop a robust alert
module that integrates with
the Arduino Mega 2560
seismic sensor system.
9. Integrate a buzzer for
audible earthquake alerts
when ground motion exceeds
a threshold.
10. Assess alert module efficacy
and responsiveness for
guaranteed timely and accurate
warnings.
PHASE 5: Evaluation and Analysis of the Entire System
15. Validate system's seismic
wave energy calculation and
classification for both geological
and human activities.
PHASE 4:
Wireless Communication and Data
Transmission
11. Develop a wireless communication protocol
to facilitate the direct transmission of seismic
data from the Arduino Mega 2560 system to a
designated receiver or server.
12. Analyze wireless system's speed,
reliability, and data integrity for seismic
transmission, factoring in distance,
interference, and data security.
13. Enhance data transmission efficiency for
seismic data through error correction,
compression, and optimized protocols.
14. Evaluate the efficiency of
data transmission to the
server, considering factors
such as speed, reliability, and
consistency.
Transcribed Image Text:PHASE 1: Data Collection 1. Optimize Arduino/ADXL for low-frequency earthquake detection. 2. Design a network for direct seismic data transmission. 3. Study how does the GSM module will send to a user without interruption. PHASE 2: Sensor System Development 4. Test the accuracy receive of the ADXL Accelerometer for each vibration. 5. Examine measures analyzing ground motion as it happens. 6. Build the circuit of the sensors and the real-time to detect seismic activity that provides alert to the Arduino. 7. Make a program code on the Arduino that will convert the readings and send to a user. 17. Identify areas for improvement based on the evaluation results and optimize the system design, algorithms, and components to enhance accuracy, reliability, and efficiency. PHASE 3: System Integration and Alert Mechanism Development 16. Evaluate system performance and reliability in real earthquakes via field tests, considering diverse intensities, frequencies, and environmental factors. 8. Develop a robust alert module that integrates with the Arduino Mega 2560 seismic sensor system. 9. Integrate a buzzer for audible earthquake alerts when ground motion exceeds a threshold. 10. Assess alert module efficacy and responsiveness for guaranteed timely and accurate warnings. PHASE 5: Evaluation and Analysis of the Entire System 15. Validate system's seismic wave energy calculation and classification for both geological and human activities. PHASE 4: Wireless Communication and Data Transmission 11. Develop a wireless communication protocol to facilitate the direct transmission of seismic data from the Arduino Mega 2560 system to a designated receiver or server. 12. Analyze wireless system's speed, reliability, and data integrity for seismic transmission, factoring in distance, interference, and data security. 13. Enhance data transmission efficiency for seismic data through error correction, compression, and optimized protocols. 14. Evaluate the efficiency of data transmission to the server, considering factors such as speed, reliability, and consistency.
Fill the table provided below
Stages
Phase 1: Data
Collection
Phase 2: Sensor
System
Development
Phase 3: System
Integration and
Alert Mechanism
Development
Phase 4: Wireless
Communication
and Data
Transmission
Phase 5:
Evaluation and
Analysis of the
Entire System
PHASE 1:
Data Collection
1. Optimize Arduino/ADXL
for low-frequency
earthquake detection.
2. Design a network for
direct seismic data
transmission.
Research Setting
NOTE: The content of the Phases on this table above are here in the figure below
PHASE 2:
Sensor System
Development
3. Study how does the
GSM module will send to
a user without
interruption.
Matrix of Methodology
Data Gathering
Respondents
Procedure
4. Test the accuracy receive of
the ADXL Accelerometer for
each vibration.
5. Examine measures analyzing
ground motion as it happens.
6. Build the circuit of the
sensors and the real-time to
detect seismic activity that
provides alert to the Arduino.
7. Make a program code on the
Arduino that will convert the
readings and send to a user.
17. Identify areas for improvement
based on the evaluation results and
optimize the system design,
algorithms, and components to
enhance accuracy, reliability, and
efficiency
PHASE 3:
System integration and
Alert Mechanism
Development
16. Evaluate system performance
and reliability in real
earthquakes via field tests,
considering diverse intensities,
frequencies, and environmental
factors.
8. Develop a robust alert
module that integrates with
the Arduino Mega 2560
seismic sensor system.
9. Integrate a buzzer for
audible earthquake alerts
when ground motion exceeds
a threshold.
10. Assess alert module efficacy
and responsiveness for
guaranteed timely and accurate
warnings.
PHASE 5: Evaluation and Analysis of the Entire System
Data Gathering
Instrument
Statistical Treatment
15. Validate system's seismic
wave energy calculation and
classification for both geological
and human activities.
PHASE 4:
Wireless Communication and Data
Transmission
11. Develop a wireless communication protocol
to facilitate the direct transmission of seismic
data from the Arduino Mega 2560 system to a
designated receiver or server.
12. Analyze wireless system's speed,
reliability, and data integrity for seismic
transmission, factoring in distance,
interference, and data security.
13. Enhance data transmission efficiency for
seismic data through error correction,
compression, and optimized protocols.
14. Evaluate the efficiency of
data transmission to the
server, considering factors
such as speed, reliability, and
consistency.
Transcribed Image Text:Fill the table provided below Stages Phase 1: Data Collection Phase 2: Sensor System Development Phase 3: System Integration and Alert Mechanism Development Phase 4: Wireless Communication and Data Transmission Phase 5: Evaluation and Analysis of the Entire System PHASE 1: Data Collection 1. Optimize Arduino/ADXL for low-frequency earthquake detection. 2. Design a network for direct seismic data transmission. Research Setting NOTE: The content of the Phases on this table above are here in the figure below PHASE 2: Sensor System Development 3. Study how does the GSM module will send to a user without interruption. Matrix of Methodology Data Gathering Respondents Procedure 4. Test the accuracy receive of the ADXL Accelerometer for each vibration. 5. Examine measures analyzing ground motion as it happens. 6. Build the circuit of the sensors and the real-time to detect seismic activity that provides alert to the Arduino. 7. Make a program code on the Arduino that will convert the readings and send to a user. 17. Identify areas for improvement based on the evaluation results and optimize the system design, algorithms, and components to enhance accuracy, reliability, and efficiency PHASE 3: System integration and Alert Mechanism Development 16. Evaluate system performance and reliability in real earthquakes via field tests, considering diverse intensities, frequencies, and environmental factors. 8. Develop a robust alert module that integrates with the Arduino Mega 2560 seismic sensor system. 9. Integrate a buzzer for audible earthquake alerts when ground motion exceeds a threshold. 10. Assess alert module efficacy and responsiveness for guaranteed timely and accurate warnings. PHASE 5: Evaluation and Analysis of the Entire System Data Gathering Instrument Statistical Treatment 15. Validate system's seismic wave energy calculation and classification for both geological and human activities. PHASE 4: Wireless Communication and Data Transmission 11. Develop a wireless communication protocol to facilitate the direct transmission of seismic data from the Arduino Mega 2560 system to a designated receiver or server. 12. Analyze wireless system's speed, reliability, and data integrity for seismic transmission, factoring in distance, interference, and data security. 13. Enhance data transmission efficiency for seismic data through error correction, compression, and optimized protocols. 14. Evaluate the efficiency of data transmission to the server, considering factors such as speed, reliability, and consistency.
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