It is perhaps the easiest to understand TDI devices by contrast with more well-known types of CCD sensors. The best known is the
staring array. In it, there are hundreds or thousands of adjacent rows of specially engineered semiconductor that react to light by accumulating charge, and slightly separated in depth from it by insulation, a tightly spaced array of gate electrodes, whose
electric field can be used to drive the accumulated charge around in a predictable and almost lossless fashion. In a staring array configuration, the image is exposed on the two-dimensional semiconductor surface, and then the resulting charge distribution over each line of the image is moved to the side, to be rapidly and sequentially read out by an electronic read amplifier. When done fast enough, this produces a snapshot of the applied photonic
flux over the sensor; the readout can proceed in parallel over the several lines, and yields a two-dimensional image of the light applied. Along with CMOS detectors which sense the photocharge accumulation
pixel by pixel instead of moving the charge out line by line, such sensors are commonly known as parts of digital cameras, from the
small to the large. A scanning array on the other hand involves just one such CCD line, or at most a couple of them. Its principle of operation is to rely on mechanical scanning, so that a single linear CCD element gets exposed to different parts of the object to be imaged, sequentially. Then the whole image is assembled from equally spaced lines through the field of view. Typical examples of this scanning mode are fax machines and other document scanners, where the imaging target is fed through at a constant linear velocity, and satellite sensing, where the constant orbital velocity of a satellite naturally exposes line after another of the underlying terrain to the transversely positioned sensor. The advantage of using a CCD sensor this way is reduced complexity, and so price, or vice versa the possibility of utilizing much more refined and so more expensive CCD technology for the single line
sensor array, for higher fidelity. CCDs can also be manufactured in configurations that are tolerant to the wide fluctuations in radiation and temperature, characteristic of space environments, and scanning ones can be made extra robust by the inclusion of multiple lines. Since the out-clocking mechanism of a well-phased CCD line is a continuous process, not divided into pixels, the eventual line-wise resolution of the image can also exceed the resolution of the gating infrastructure, leading to higher resolution than a pixel-based sensor. CCDs are also easier to make for cryogenic temperatures, such as are needed e.g. for
far-infrared astronomy.
Motion At the same time, the continuous operation and slow, line-discrete readout also leads to a problem: if anything moves within the scene to be imaged, there will be blurring and tearing between lines. Wherever some accumulated packet of charge within a CCD line is moving on the sensor chip, any extra light shone upon it will lead to more charge, even if it comes from a wrong direction, or a newer moment of acquisition than intended. It will register just the same, so that it integrates over time to whatever will eventually be read out. This leads to what is in
cinematography called
motion blur, and since the readout of the multiple lines of the typical CCD array occurs at different successive times, it also causes
screen tearing. In TDI mode, motion blur and the pseudo-analogue nature of CCDs is turned from a fault into a special-purpose asset. The line or 2D array is turned 90 degrees so that the lines in the CCD sensor follow the expected trajectory of the object of interest in the field of view. Then, the readout speed from the sensor is adjusted so that the charge packets in the imaging plane track the object, accumulating charge over time. This is effectively the same as spinning the spacecraft or other platform to match the viewing angle towards an object; it yields time integration in the digital domain, instead of the physical one. Physical tracking and superimposition of images can be applied in addition, as more traditional forms of TDI. With the high sensitivity of CCD sensors, into the
photon counting regime, this can lead to extremely high detection and measurement sensitivity. Additionally, it is difficult to achieve the kinds of coherent measurement gains with digital technologies besides CCDs, because they suffer from more prominent
aliasing. == Technology specific to TDI CCD ==