NOIL1SN3000A-GDC ON Semiconductor, NOIL1SN3000A-GDC Datasheet - Page 41

NOIL1SN3000A-GDC

Manufacturer Part Number

NOIL1SN3000A-GDC

Description

Manufacturer

ON Semiconductor

Datasheet

1.NOIL1SN3000A-GDC.pdf (58 pages)

Specifications of NOIL1SN3000A-GDC

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Windowing

The parameters to configure this window are:

Readout starts only at odd kernel positions. As a result

possible start positions are 64 columns (two kernels)

separated from each other.

granularity of 1.

in full frame mode, because only the relevant part of the

image array is accessed. As a result, it is possible to achieve

higher frame rates.

Restrictions to Windowing

partial windows must be done with some restrictions.

•

A fully configurable window can be selected for readout.

X_START: It is the start position for the X readout.

X_kernels: The number of kernels to be read out.

Y_start: The starting line of the readout window.

Y_end: The end line of the readout window,

For windowing, the effective readout time is smaller than

To ensure correct operation of the sensor, the readout of

The minimum window size is 4 kernels (128 pixels) in

the x-direction and 1 line in the y-direction.

In the x-direction, windowing can only start at an odd

kernel (kernel1, kernel3, and so on). Then number of

kernels to readout is not subject to an odd-even

restriction.

The sum of the ROT_TIMER and the

NB_OF_KERNELS spi registers should always be an

even number.

y-start

y-end

Figure 35. Window Selected for Readout

x-start

1696 pixels

x-end

1710 pixels

ADDITIONAL FEATURES

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only change in steps of 64 pixels. If the number of kernels

to readout is decreased with one and the ROT is already at

the minimum value, then the ROT time should be increased

with one (clock cycle) to compensate. The framerate

remains unchanged by this, but the data rate drops.

Sub Sampling

Reverse Scan

Multiple Windows

Dual Slopes

capability of the sensor. The four colored lines in Figure 36

represents analog signals of the photodiode of four pixels,

which decreases as a result of exposure. The slope is

determined by the amount of light at each pixel (the more

light, the steeper the slope). When the pixels reach the

saturation level, the analog does not change despite further

exposure. Without the dual slope capabilities, the pixels p3

and p4 are saturated before the end of the exposure time, and

no signal is received. However, when using dual slopes, the

analog signal is reset to a second reset level (lower than the

original) before the integration time ends. The analog signal

starts decreasing with the same slope as before, and pixels

that were saturated before could be nonsaturated at read out

time. For pixels that never reach any of the reset levels (for

example, p1 and p2), there is no difference between single

and multiple slope operation.

(typical at 90%, configurable by the user), it is possible to

have a nonsaturated pixel value even for pixels that receive

a huge amount of light.

pins.

This means that for a fixed ROT time, the window size can

Not supported by LUPA3000.

Dynamic range can be extended by the dual slope

By choosing the time stamps of the double slope resets

The reset levels are configured through external (power)

NOIL1SN3000A-GDC ON Semiconductor, NOIL1SN3000A-GDC Datasheet - Page 41

NOIL1SN3000A-GDC

Specifications of NOIL1SN3000A-GDC

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