Specifications

connect our own to them. The MPPT charge controllers will help regulate the power

output and will ensure that it stays within safe levels for the battery. This information will

also be fed into the same microcontroller as the second power input source.

Next, we will need to know the amount of power being drawn between all of our

devices. This would include such things as the laptop, the projector, the LCD display,

and any microcontrollers used. Since MSP430 microcontrollers are known for their low

power usage, their power usage is negligible. The rest of the components, however,

will need to be hooked up to sensors and their power usage fed into the microcontroller.

With all of this information, we will be able to calculate the total power usage of the

system. If the energy coming in from our power sources is greater than the power being

used by our components, then we will be storing energy in the battery and the LCD will

reflect this. If, however, we are not drawing in as much energy as we are using, our

system will be draining the battery. This will also need to be displayed on our LCD

screen, as well as an estimation of how much longer the battery can power the

components until it runs out of energy.

The power calculations can all be programmed on one microcontroller. The data can be

taken in, and the microcontroller can do all of the arithmetic operations required in real

time. This information can then be used to determine what action the LCD will take to

output the proper display to the user.

In order to calculate the power being used, the voltage at the load and the current going

to the load must be measured. In order to do this, the battery voltage must be scaled

down to a voltage readable by the microcontroller, which is -0.3V to Vcc+0.3V. This can

be done with a simple voltage divider placed on the PCB. In this case we will be using a

Vcc of 3.5V, so the range will be from -0.3V to 3.8V. This means we need to drop our

maximum voltage of 13.1V to 3.8V, so R1 should be equal to 2KΩ and R2 should be

equal to 723Ω. This circuit can be viewed in the figure below. The circuit below can be

included on the PCB created for the microcontrollers, or may be on a separate PCB,

depending on final board sizing requirements.

Battery Positive

Battery Negative

2KΩ

723Ω

Battery Voltage to Microcontroller

Figure 57 - Voltage Divider to Feed Battery Voltage to Microcontroller

The current going to the load will be calculated using a Hall Effect Sensor. Since there

will need to be multiple of these sensors, they will be placed on their own circuit board.