Smartwatch for direct and indirect communication between parent and child

1 . A smartwatch for a child, comprising: a U-shaped body having a screen side, a base, a watch band extending edge, a watch band latching edge opposite the watch band extending edge, a button edge having a first aperture for a first button and a second aperture for a second button, a communicator edge opposite the button edge, the communicator edge having a speaker aperture and a microphone aperture; a touch screen located on the screen side; a display module located on the screen side adjacent to the touch screen; a light module located on the screen side adjacent to the display module; a speaker located within the U-shaped body beneath the display module, wherein a sound generating end of the speaker is configured to extend into the speaker aperture; a printed circuit board located within the U-shaped body, wherein the printed circuit board is configured to hold the speaker, a battery, a wireless charger, a near field communications unit, a signal booster, and a microprocessor configured with electrical circuitry, a memory and at least one processor; a photoplethysmography (PPG) sensor embedded in the base beneath the printed circuit board; an electrodermal activity (EDA) sensor embedded in the base beneath the printed circuit board; and a watch band connected to the watch band extending edge, wherein a length of the watch band is configured to fit a wrist of a child. 2 . The smartwatch of claim 1 , further comprising: a wiring harness located within the printed circuit board, wherein the wiring harness is configured to connect the microprocessor to the battery, the wireless charger, the near field communications unit, the signal booster, the memory, the speaker, the microphone, the display module, the light module, the touch screen, the PPG sensor and the EDA sensor. 3 . The smartwatch of claim 2 , further comprising: a PPG measurement surface located on a side of the PPG sensor, wherein the PPG measurement surface is flush with an outside surface of the U-shaped body. 4 . The smartwatch of claim 3 , further comprising: a plurality of high-intensity infrared light-emitting diodes located within the PPG measurement surface of the PPG sensor; and a plurality of photodiodes located within the PPG measurement surface of the PPG sensor, wherein the microprocessor is configured to generate PPG measurement commands which actuate the plurality of high-intensity infrared light-emitting diodes to generate an infrared light towards the wrist of the child, and wherein the plurality of photodiodes are configured to measure an infrared light reflected from the wrist of the child, determine a blood oxygenation level and a pulse rate of the child and transmit the blood oxygenation level and the pulse rate of the child through the wiring harness to the microprocessor. 5 . The smartwatch of claim 4 , further comprising: an EDA measurement surface located on a side of the EDA sensor, wherein the EDA measurement surface is flush with an outside surface of the U-shaped body. 6 . The smartwatch of claim 5 , further comprising: a sense electrode located within the EDA measurement surface of the EDA sensor at a first end; and a counter electrode located within the EDA measurement surface of the EDA sensor at a second end separated from the first end by a distance less than a length of the EDA sensor, wherein the microprocessor is configured to generate EDA measurement commands which actuate the sense electrode to generate a current, and wherein the EDA sensor is configured to measure a voltage between the sense electrode and the counter electrode, determine an electrical conductivity of the wrist of the child and transmit the electrical conductivity through the wiring harness to the microprocessor. 7 . The smartwatch of claim 6 , further comprising: a measurement database located within the memory, wherein the measurement database is configured with data linking moods of the child to PPG and EDA measurements, wherein the microprocessor is configured to receive the blood oxygenation level and pulse rate of the child from the PPG sensor, receive the electrical conductivity of the wrist of the child from the EDA sensor, access the measurement database to match the PPG measurements and the EDA measurements to a mood of the child, and generate a mood modifying message and a mood communication packet; wherein the display module is configured to display the mood modifying message; and the near field communications unit is configured to transmit the mood communication packet. 8 . The smartwatch of claim 7 , further comprising: a gyroscopic accelerometer located on the printed circuit board and connected to the microprocessor through the wiring harness, wherein the gyroscopic accelerometer is configured to measure changes in an orientation and a rotation of the smartwatch and transmit the changes in the orientation and rotation through the wiring harness to the microprocessor. 9 . The smartwatch of claim 8 , further comprising: data records located in the measurement database which link orientation and rotation of the smartwatch to activity levels of the child, wherein the microprocessor is configured to monitor the activity levels and generate an activity message related to the activity levels, wherein the display module is configured to display the activity message; and the near field communications unit is configured to transmit the activity levels and movement activity message in an activity communication packet. 10 . The smartwatch of claim 9 , wherein the microprocessor is configured to monitor the activity levels in time intervals of about 30 minutes and generate the movement activity message when the activity level of the child does not change within the time interval. 11 . The smartwatch of claim 10 , further comprising: a video game database located within the memory, wherein the video game database is configured to store mood modifying video games and activity video games; an avatar program stored within the memory; wherein the at least one processor is configured to execute the program instructions to one of: access a mood modifying video game based on the mood of the child and display the avatar on the display module with instructions to click on the avatar to play the mood modifying video game; and access an activity video game based on the activity level of the child and display the avatar on the display module with instructions to click on the avatar to play the activity video game. 12 . The smartwatch of claim 1 , further comprising: a battery charger having a charge end configured to attach magnetically to the base and a transformer end configured to connect to a power source, wherein the battery charger is configured to charge the battery when the base is attached to the charge end. 13 . The smartwatch of claim 1 , further comprising: an ON/OFF button located in a first aperture, wherein the ON/OFF button is connected to the microprocessor and is configured to one of turn ON the smartwatch and turn OFF the smartwatch when the ON/OFF button is depressed. 14 . The smartwatch of claim 1 , further comprising: a plurality of pillars located with the watch band at spaced locations, wherein each pillar includes a haptic engine; a plurality of wires embedded within the watch band, wherein the plurality of wires are configured to connect each haptic engine to the microprocessor, wherein the microprocessor is configured to generate drive signals to selectively activate each haptic engine located within the watch band. 15 . A smartwatch communication system for facilitat