In addition to large thermal drift, typical magnetic current sensors suffer an additional 2% to 3% drift in sensitivity due to aging over the lifetime of the device. The same proprietary compensation techniques used in the TMCS1123 to reduce temperature drift are also used to greatly reduce lifetime drift due to aging from stress and environmental conditions especially at high operating temperatures. As shown in the Electrical CharacteristicsElectrical CharacteristicsElectrical CharacteristicsElectrical Characteristics, the TMCS1123 has industry leading lifetime sensitivity drift realized after Highly Accelerated Stress Tests (HAST) at 130°C and 85% relative humidity (RH) during standard three lot AEC-Q100 qualifications. Low sensitivity and offset drift within the bounds specified in the Electrical CharacteristicsElectrical CharacteristicsElectrical CharacteristicsElectrical Characteristics are also observed after 1000 hour, 125°C high temperature operating life stress tests are performed as prescribed by AEC-Q100 qualifications. These tests mimic typical device lifetime operation, and show device performance variation due to aging is vastly improved compared with typical magnetic current sensors. Figure 8-2 and Figure 8-3 show the sensitivity and offset drift after a 1000 hour, 125°C high temperature operating life stress test as specified by AEC-Q100. This test mimics typical device lifetime operation, and shows the likely device performance variation due to aging is vastly improved compared to typical magnetic sensors.

Figure 8-2 Sensitivity Error Drift After AEC-Q100 High Temperature Operating Life Stress Test

Figure 8-3 Input-Referred Offset Drift After AEC-Q100 High Temperature Operating Life Stress Test