Pyroelectric generator

The invention claimed is: 1. A poled pyroelectric device, comprising: a plurality of layers of a polar dielectric material having a pyroelectric coefficient, p, wherein each layer exhibits pyroelectric properties, and wherein said polar dielectric material is an undoped or doped BaTiO 3 (barium titanate); a plurality of conductive electrodes layers, wherein each conductive electrodes layer is substantially in contact with at least a portion of one surface of a respective at least one of said plurality of layers of polar dielectric material, wherein the conductive electrodes layers are arranged vertically one on top of another, and separated by polar dielectric material layers in-between, and the conductive electrodes layers are alternately electrically interconnected together in a parallel configuration as to form a series of capacitors comprised of said plurality of layers of polar dielectric material and plurality of conductive electrodes layers, wherein odd conductive electrodes layers are electrically connected at one end and even conductive electrodes layers are electrically connected at an opposite end so that both external terminations form electrical contacts of capacitors plates, wherein the pyroelectric device is poled by a poling process such that ferroelectric domains of the polar dielectric material are aligned with their dipoles in the same direction, the poling process consisting in: heating the device at a temperature in the range 120° C. to 150° C., applying an electric field in the range 10 kilovolt/cm to 60 kilovolt/cm for about 2 hours, and then allowing the device to freely cool down to room temperature; or cooling down the device to −18° C., then exposing the device at −18° C. for two hours to an electric field in the range 50 kilovolt/cm to 350 kilovolt/cm, and allowing subsequently the device to return freely to room temperature. 2. The pyroelectric device of claim 1 , wherein the plurality of layers of the polar dielectric material and the plurality of conductive electrodes are stacked vertically one on top of another. 3. The pyroelectric device of claim 1 , wherein the series of capacitors comprises at least two or three capacitors. 4. The pyroelectric device of claim 1 , wherein the series of capacitors comprises more than ten capacitors. 5. The pyroelectric device of claim 1 , wherein the plurality of layers of the polar dielectric material and the plurality of conductive electrodes stacked vertically one on top of another are integrated in an MLCC capacitor (Multi-Layer Ceramic Capacitor) of a size smaller than 5 mm or smaller than 1 mm. 6. The pyroelectric device of claim 1 , wherein at least one of said electrodes is a precious-metal-electrode (PME), comprising platinum, gold, silver-palladium, or, alternatively, a conductive oxide, iridium oxide, nickel or, a base-metal-electrode (BME). 7. The pyroelectric device of claim 1 , wherein the pyroelectric device comprises at least a top electrode, a layer of barium titanate, a first interim electrode, another layer of barium titanate, a second interim electrode, a third layer of barium titanate, and a bottom electrode resulting in at least three capacitors electrically connected in parallel. 8. The pyroelectric device of claim 1 , wherein said pyroelectric device has an output response resulting from exposure to temperature variations. 9. The pyroelectric device of claim 8 , wherein the output response is an output current proportional to the area A of the series of capacitors, or a pyroelectric current, I, monitored for example as a pyroelectric voltage drop, V, across an external resistor, or as a power, or as a signal obtained processing the output response of the pyroelectric device through a suitable electronic device, being an operational amplifier. 10. The pyroelectric device of claim 1 , wherein said pyroelectric device is used in either a contact or in a non-contact temperature variation measurement device. 11. Use of the pyroelectric device of claim 1 for energy harvesting. 12. A temperature variation measurement device comprising a pyroelectric device according to claim 1 . 13. A method of measuring a temperature variation comprising the step of measuring the output response of a pyroelectric device according to claim 1 . 14. The pyroelectric device of claim 1 , wherein the number of the layers of a polar dielectric material is between 100 and 500. 15. The pyroelectric device of claim 14 , wherein an active area of a single layer of a polar dielectric material is between 1 and 10 mm 2 . 16. The pyroelectric device of claim 14 , wherein a total effective area for the pyroelectric device is between 500 and 3000 mm 2 . 17. The pyroelectric device of claim 1 , wherein the capacitors are electrically pre-charged.