Abstract
Herein, we present a low-power cyclic Vernier two-step time-to-digital converter (TDC) that achieves a wide input range with good linearity. Since traditional approaches require a large area or high power to achieve an input range >300 ns, we solve this problem by proposing a simple yet efficient TDC suitable for time-of-flight (TOF) sensors. In previous studies using the cyclic structure, the effect of startup time on the linearity of the TDC is not described. Thus, the achievable linearity has been limited when the TDC is used for applications requiring a high input range. We solve this problem by using a simple yet effective technique to compensate. The proposed technique is realized using (1) digitally-controlled oscillators (DCOs) that have dual frequency control and matched startup time; (2) an alignment detector that performs startup time correction by proper timing control; and (3) a fully symmetric arbiter that precisely detects the instant of edge alignment. To achieve a fine resolution for the cyclic Vernier TDC, we design two closely-matched DCOs with dual frequency control. The alignment detector performs the critical task of cancelling startup time via timing control. The detector is delay-compensated by using a dummy to provide matched loading for the two DCOs. To enhance the detection speed under low power, a current-reuse approach is employed for the arbiter. The TDC is fabricated using a 0.18 μm complementary metal–oxide–semiconductor (CMOS) process in a compact chip area of 0.028 mm2. Measured results show a dynamic range of 355 ns and a resolution of 377 ps. When the result is applied for TOF sensing, it corresponds to a distance range of 53.2 m and a resolution of 5.65 cm. Over a relatively large input range, good linearity is achieved, which is indicated by a DNL of 0.28 LSBrms and an INL of 0.96 LSBrms. The result corresponds to root mean square (RMS) error distance of 5.42 cm. The result is achieved by consuming a relatively low power of 0.65 mW.
Highlights
A time-to-digital converter (TDC) is widely used to quantize and digitize time interval information and regarded as one of the most important time sensor [1]
Over a relatively large input range, good linearity is achieved, which is indicated by a differential nonlinearity (DNL) of 0.28 LSBrms and an integral nonlinearity (INL) of 0.96 LSBrms
In reference [2], a TDC is integrated with the single-photon avalanche diodes (SPAD) to form the pixel of the sensor, which is used for the image sensor in short-range and for altimeters in the long-range applications
Summary
A time-to-digital converter (TDC) is widely used to quantize and digitize time interval information and regarded as one of the most important time sensor [1]. The time interval between pulse signals is used for various sensing applications, for example, altitude sensing [2], depth sensing [3], respiration rate sensing [4], biomedical image sensing [5,6], and distance sensing for navigation [7]. Sensors 2018, 18, 3948 the shape of an object by measuring the distance between the sensor pixels and the target object [3]. The fluorescence lifetime image (FLIM) sensor uses TDCs to extract important information for identifying cell microstructure [5], which is not usually available from intensity image sensing. TDCs have great utility in positron emission tomography (PET)
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