A parameter optimization method for air wave pressure massager based on deep learning algorithm
A deep learning and optimization method technology, applied in the medical field, can solve the problems of high retraining costs and low accuracy, and achieve the effect of saving redundant equipment
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specific Embodiment approach 1
[0026] Specific embodiment one: a method for optimizing parameters of an air wave pressure massager based on a deep learning algorithm comprises the following steps:
[0027] Step 1: Collect the user's blood pressure and pulse data as a training set;
[0028] Step 2: Establish a deep learning structure model on the server;
[0029] Step 3: Input the training set of step 1 into the deep learning structure model established in step 2 for training, and obtain the trained deep learning structure model;
[0030] Step 4: Collect the blood pressure and pulse data of the user of the air wave pressure massager, input it into the deep learning structure model after training, the model outputs the parameters of the air wave pressure massager, and adjust the air wave pressure massager according to the output parameters of the air wave pressure massager Massage intensity, massage frequency and massage position, the parameters of the air wave pressure massager include massage intensity, ma...
specific Embodiment approach 2
[0044] Specific embodiment two: the difference between this embodiment and specific embodiment one is: the specific process of establishing the deep learning structure model on the server in the second step is:
[0045] The user's blood pressure and pulse data collected in step 1 are used as input, and the parameters of the air wave pressure massager are output through the activation function layer and the fully connected layer.
[0046] Other steps and parameters are the same as those in Embodiment 1.
specific Embodiment approach 3
[0047] Embodiment 3: The difference between this embodiment and Embodiment 1 or 2 is that the activation function of the excitation function layer is specifically:
[0048] Preprocess the collected user's blood pressure and pulse data;
[0049] Set the threshold range of blood pressure and pulse; if it is higher than the threshold range, the difference between it and the upper limit of the threshold is recorded as positive; if it is lower than the threshold range, the difference between it and the lower limit of the threshold is recorded as negative; in the threshold range Internally recorded as 0;
[0050] Take the softplus function for the preprocessed value as the activation function;
[0051] The softplus function is log(1+exp(t)), where t is a preprocessed value.
[0052] Other steps and parameters are the same as those in Embodiment 1 or Embodiment 2.
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