Apparatuses and methods for shape-memory alloys and sensing

1 . An aircraft assembly comprising: a sensor; a cable connected to the sensor; and a shape-memory alloy (SMA) element connected to the cable, wherein the SMA element is configured to change shape and control tension in the cable. 2 . The aircraft assembly of claim 1 , wherein the SMA element is configured to undergo a phase transformation in response to temperature or load to change shape. 3 . The aircraft assembly of claim 1 , wherein the SMA element is configured to undergo a phase transformation in response to an input from a heater or an electrical power supply to change shape. 4 . The aircraft assembly of claim 1 , wherein the SMA element (510) is configured to undergo a phase transformation at a threshold temperature within a range of -100 °C to 200 °C to change shape. 5 . The aircraft assembly of claim 1 , wherein the SMA element is configured to undergo a first phase transformation at a first temperature, and wherein the SMA element is configured to change shape during the first phase transformation, and wherein the SMA element is configured to undergo a second phase transformation at a second temperature, and wherein the SMA element is configured to change shape during the second phase transformation. 6 . The aircraft assembly of claim 1 , wherein the change in shape of the SMA element is in response to a stress and with a temperature of the SMA element being greater than an austenite finish temperature. 7 . The aircraft assembly of claim 1 , wherein the cable is configured to change in length due to thermal expansion at a target temperature, and wherein the change in shape of the SMA element corresponds to the change in length of the cable. 8 . The aircraft assembly of claim 1 , wherein the change in shape of the SMA element offsets a loss of tension in the cable. 9 . The aircraft assembly of claim 1 , wherein the change in shape of the SMA element comprises increasing, decreasing, and or maintaining the tension in the cable. 10 . An aircraft comprising: a fuselage; a wing supported by the fuselage; and an aircraft assembly comprising: a sensor; a cable connected to the sensor; and a shape-memory alloy (SMA) element connected to the cable, wherein the SMA element is configured to change shape and control tension in the cable. 11 . The aircraft of claim 10 , wherein the sensor is configured to generate a skew angle signal in response to displacement of the cable, and wherein the change in shape of the SMA element offsetting the change in length of the cable prevents the sensor from generating the skew angle signal. 12 . The aircraft of claim 10 , wherein the wing comprises a control surface connected to the cable, and wherein the sensor is configured to detect displacement of the cable as a skew angle of the control surface, wherein the skew angle is a deviation of a portion of the control surface from a target position. 13 . The aircraft of claim 10 , wherein the change in shape of the SMA element is based on a change in length of the cable. 14 . The aircraft of claim 10 , wherein the aircraft comprises an anchor, wherein the SMA element comprises a first end and a second end, wherein the first end of the SMA element is connected to the cable, and wherein the second end of the SMA element is connected to the anchor. 15 . The aircraft of claim 10 , wherein the SMA element is comprised of a nickel titanium (NiTi) alloy and at least one of: iron (Fe), niobium (Nb), hafnium (Hf), zirconium (Zr), platinum (Pt), palladium (Pd), and/or copper (Cu). 16 . The aircraft of claim 10 , wherein the aircraft comprises a control surface and the control surface is connected to the cable, and wherein the sensor is configured to detect displacement of the cable as a skew angle of the control surface, wherein a change in shape of the SMA element offsets a loss of tension in the cable and prevents the sensor from generating a slack signal in response to the loss of tension. 17 . The aircraft of claim 10 , wherein the SMA element is configured to undergo a first phase transformation in response to an ambient temperature within an ambient temperature range, and wherein the SMA element is configured to change shape during the first phase transformation, and wherein the SMA element is configured to undergo a second phase transformation in response to an input from a heater or an electrical power supply at a second temperature, and wherein the SMA element is configured to change shape during the second phase transformation. 18 . The aircraft of claim 10 , wherein the change in shape of the SMA element comprises applying a force against the cable. 19 . A method comprising: changing a shape of a shape-memory alloy (SMA) element by an amount corresponding to a change in a length of a cable, wherein an aircraft assembly comprises: a sensor; the cable connected to the sensor; and the SMA element connected to the cable. 20 . The method of claim 19 , further comprising: detecting displacement of the cable with the sensor; generating a skew angle signal in response to displacement of the cable; and offsetting the change in the length of the cable via the change in the shape of the SMA element such that the skew angle signal is not generated.