Thermal management system for electronic components with thermoelectric element

What is claimed is: 1. A cooling and heating system, comprising: a first thermoelectric element disposed near a first electronic component, the first electronic component including a chip or a memory package, the first thermoelectric element capable of operating in a cooling mode or a heating mode dependent upon a current flow direction of a first electric current flowing therethrough; a package lid covering the first electronic component, wherein the first thermoelectric element is disposed inside the package lid; a first polarity change circuit coupled to the first thermoelectric element to switch the current flow direction of the first electric current, the first polarity change circuit including a first plurality of switches; a first buck-boost converter coupled to a power source, wherein the first buck-boost converter includes a first capacitor, a second capacitor, an inductor, a transistor and a diode, wherein the first capacitor is directly connected to an electromagnetic interference (EMI)/input filter, wherein the second capacitor is directly connected to the first polarity change circuit, and wherein the first polarity change circuit is configured to switch the current flow direction of the first electric current received from an output of the first buck-boost converter; a second thermoelectric element, disposed near a second electronic component, the second electronic component including one or more non-heavy computing units, the second thermoelectric element capable of operating in a cooling mode or a heating mode dependent upon a current flow direction of a second electric current flowing therethrough, the second electronic component having a second cooling/heating level different than a first cooling/heating level of the first electronic component; a thermal pad directly attached to the second thermoelectric element for a heat transfer to or from the second electronic component; a second polarity change circuit coupled to the second thermoelectric element to switch the current flow direction of the second electric current, the second polarity change circuit including a second plurality of switches; a second buck-boost converter coupled to the power source or another power source, the second buck-boost converter directly connected to the second polarity change circuit, wherein the second polarity change circuit is configured to switch the current flow direction of the second electric current received from an output of the second buck-boost converter; and a controller coupled to the first plurality of switches of the first polarity change circuit to control the current flow direction of the first electric current flowing in the first thermoelectric element and coupled to the second plurality of switches of the second polarity change circuit to control the current flow direction of the second electric current flowing in the second thermoelectric element, wherein the controller is configured to measure a temperature of a first side of the first thermoelectric element and a temperature of a second side of the first thermoelectric element, and to control the current flow direction of the first electric current in the first thermoelectric element based on the temperature of the first side of the first thermoelectric element and the temperature of the second side of the first thermoelectric element. 2. The system of claim 1 , further comprising a heat transferring element coupled to the first thermoelectric element, the heat transferring element including a heatsink or a cold plate. 3. The system of claim 1 , wherein the first polarity change circuit comprises: a first switch of the first plurality of switches coupled between a first output terminal of the output of the first buck-boost converter and a first terminal of the first thermoelectric element; a second switch of the first plurality of switches coupled between the first output terminal of the output of the first buck-boost converter and a second terminal of the first thermoelectric element; a third switch of the first plurality of switches coupled between a second output terminal of the output of the first buck-boost converter and the second terminal of the first thermoelectric element; and a fourth switch of the first plurality of switches coupled between the second output terminal of the output of the first buck-boost converter and the first terminal of the first thermoelectric element. 4. The system of claim 3 , wherein when the first switch and the third switch are turned on while the second switch and fourth switch are turned off, the current flow direction of the first electric current in a first direction, and wherein when the second switch and the fourth switch are turned on while the first switch and the third switch are turned off, the current flow direction of the first electric current is in a second direction opposite to the first direction. 5. The system of claim 1 , wherein the controller is further configured to determine: the current flow direction of the first electric current in the first thermoelectric element based on a minimum temperature allowed for the first electronic component, or the current flow direction of the second electric current in the second thermoelectric element based on a minimum temperature allowed for the second electronic component. 6. The system of claim 1 , wherein the controller is further configured to determine: the current flow direction of the first electric current in the first thermoelectric element based on a target temperature for the first electronic component, or the current flow direction of the second electric current in the second thermoelectric element based on a target temperature for the second electronic component. 7. The system of claim 1 , wherein the controller is configured to determine: the current flow direction of the first electric current to be in a direction to heat up the first electronic component in response to determining that the temperature of the first side of the first thermoelectric element is lower than a minimum temperature allowable for the first electronic component, or the current flow direction of the second electric current to be in a direction to heat up the first electronic component in response to determining that a temperature of the first side of the second thermoelectric element is lower than a minimum temperature allowable for the second electronic component. 8. The system of claim 1 , wherein the controller is configured to determine: the current flow direction of the first electric current to be in a direction to cool the first electronic component in response to determining that the temperature of the first side of the first thermoelectric element is higher than the temperature of the second side of the first thermoelectric element, or the current flow direction of the second electric current to be in a direction to the second electronic component in response to determining that a temperature of the first side of the second thermoelectric element is higher than a temperature of the second side of the second thermoelectric element. 9. The system of claim 1 , wherein the system includes the cooling mode of the first thermoelectric element to cool the first electronic component, the cooling mode of the second thermoelectric element to cool the second electronic component, the heating mode of the first thermoelectric element to heat the first electronic component, and the heating mode of the second thermoelectric element to heat the second electronic component, and wherein no extra component is needed when switching between the cooling mode and the heating mode of the first thermoelectric element and no extra component is needed when switching between the cooling mo