上海泰克尔体育科技有限责任公司

Shanghai Teker Sports Technology Co., Ltd.
 
Our Scope of Services
Neurobiomechanics
Sports Biomechanics
Rehabilitative Biomechanics
Musculoskeletal Biomechanics
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Neurobiomechanics studies brain activation and its relation to movement using devices like EEG and fNIRS. We provide data analysis for these neuroscience tools.
Sports biomechanics focuses on the science of movement techniques. We provide data analysis for equipment like optical motion capture and force plates.
Musculoskeletal biomechanics studies how bones and muscles interact and affect external performance.We offer data processing and analysis services in this field, including personalized musculoskeletal modeling.
Rehabilitative biomechanics is the science of helping patients regain mobility and enhance their quality of life. We offer feasibility analysis for rehabilitation equipment and personalized biomechanical data analysis for patients.
Comming Soon
Computational Biomechanics
Others
In addition to the primary services outlined here, we can also assist users in drafting analysis reports and conducting statistical data processing.
Computational biomechanics refers to the science of using various innovative methods to process data. We offer various data mining and secondary computational methods, such as principal component analysis, non-negative matrix factorization, ICA analysis, and more.
Our Project Case
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Investigating Human Muscle Responses to Vibration Using AnyBody
Summary: Observing muscle responses to external vibrations is potentially crucial for optimizing seat design, as muscles must contract vigorously to counteract disturbances, potentially leading to quicker fatigue in such scenarios. Utilizing the AnyBody Modeling System, various types and frequencies of vibrations can be applied at the connection between the human body and the seat. The vibrations will be conducted upwards through the pelvis to the upper limbs, allowing observation of the attenuation of vibrations along the conduction path and the muscle responses to them.
Process:
1. Use Solidworks to create a 3D model of the seat, establish appropriate fitting relationships, and save it as an assembly.
2. Process the model using the interface plugin between AnyBody and Solidworks, and import it into AnyBody.
3. Set the fitting relationship between the human model and the seat, establishing contact points at the thighs and buttocks.
4. Configure the drivers to deliver vibrations to the human body at a specific frequency. Run the simulation to obtain results.
Results: The activation response curves of all lower limb muscles to sinusoidal vibrations at a frequency of 3, with the activation of the vastus lateralis muscle nearing 1. This indicates that the muscles will fatigue quickly under these conditions. The second graph displays the predicted contact forces at a specific contact point between the seat and the human body under vibration. The vertical force peaks at 250 Newtons and drops to a minimum of 100 Newtons.
Investigating the Rehabilitation Effects on Muscles
Summary: Patients may experience muscle strength degradation in certain areas due to various reasons such as bed rest, impacting their normal life and work. Rehabilitation devices are needed to stimulate atrophied muscles for quick strength recovery. The AnyBody analysis evaluates the activation effect of lower limb muscles when the ankle joint exercises on the device at specific angular velocities and angles, assessing the rationality of the device's design.
Process:
1. Use Solidworks to create a 3D model of the rehabilitation device, establish appropriate fitting relationships, and save it as an assembly.
2. Process the model using the interface plugin between AnyBody and Solidworks, and import it into AnyBody.
3. Set the fitting relationship between the human model and the seat, establishing contact points at the thighs and buttocks.
4. Set the contact relationship between the right foot and the rehabilitation device.
5. Consider the movement characteristics of the device, setting up corresponding rotational or translational drivers.
6.  Obtain the simulation results.
Results: Within the range of -13 to +13 degrees for inversion (-) / eversion (+), the average muscle activation level of all evertor muscles increased from 15% to 40%. From plantar flexion (-) / dorsiflexion (+) within the -20 to +20 degrees range, the activation level of all dorsiflexor muscles increased from 20% to 45%.
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Who We are?
We are Shanghai Teker Sports Science and Technology Co., Ltd., established in 2023 in the Science and Technology Park of Shanghai University of Sport. Teker is committed to providing mature and personalized data processing and analysis solutions for the field of sports science in China, even the world. We believe that researchers should focus their efforts on generating ideas and conducting experiments, rather than spending a significant amount of time and energy on data processing and analysis.
Why choose us? 1. Prioritize customer privacy as the topmost concern in our services. 2. Serve every customer with patience and responsibility, regardless of their identity, status, or educational background. 3. Our company is located in Shanghai, China. China is a developing country, where the cost of labor is very low, so our quotation is very competitive. 4. Support the signing of confidentiality agreements with customers and ensure the confidentiality of customer data through insurance measures.
About Us
+8618366748292
qfnucss-yangchen@foxmail.com jinpf018@gmail.com
350 Hengren Road, Yangpu District, Shanghai, China
Using Wechat to contact us.