XRD9825 Datasheet, PDF(26/33 Page) Exar Corporation – 16-Bit Linear CIS/CCD Sensor Signal Processor with Serial Control

English

English German Russian Spanish Italian Polish Chinese Japanese Korean French Portuguese	Language :

XRD9825 Datasheet, PDF (26/33 Pages) Exar Corporation – 16-Bit Linear CIS/CCD Sensor Signal Processor with Serial Control

◁

XRD9825

Mode 2. DC Coupled

Typical CCDs have outputs with black references.

Therefore, DC Coupled is not recommended for CCD

applications.

Offset Control DAC

The offset DAC is controlled by 8 bits. The offset range

is 800 mV ranging from -200 mV to +600 mV (when DB5

is set to 0) and -400 mV to +400 mV (when DB5 is set

to 1). Therefore, the resolution of the 8-Bit offset DAC

is 3.14 mV. However, the XRD9825 has +/- 100 mV

reserved for internal offsets. Therefore, the effective

range for adjusting for CIS offsets or black reference is

600 mV. The offset adjustment is used primarily to

correct for the difference between the black level of the

image sensor and the bottom ladder reference voltage

(VRB) of the ADC. By adjusting the black level to

correspond to VRB, the entire range of the ADC can be

used.

If the offset of the CIS output is greater than 500 mV an

external reference can be applied to VDCEXT. The

external reference can be used to adjust for large

offsets only when the internal mode is configured

through the serial port.

Since the offset DAC adjustment is done before the

gain stage, it is gain-dependent. For example, if the

gain needs to be changed between lines (red to blue,

etc.), the offset is calibrated before the signal passes

through the PGA.

PGA (Programmable Gain Amplifier) DAC

The gain of the input waveform is controlled by a 6-Bit

PGA. The PGA is used along with the offset DAC for

the purpose of using the entire range of the ADC. The

PGA has a linear gain from 1 to 10. Figure 19 is a plot

of the transfer curve for the PGA gain.

PGA GAIN TRANSFER CURVE

GAIN 1 - 10

CODE

Figure 20. Transfer Curve for the 6-Bit PGA

After the signal is level shifted to correspond with the

bottom ladder reference voltage, the system can be

calibrated such that a white video pixel can represent

the top ladder reference voltage to the ADC. This allows

for a full scale conversion maximizing the resolution of

the ADC.

Analog to Digital Converter

The ADC is a 16-bit, 10 MSPS analog-to-digital con-

verter for high speed and high accuracy. The ADC uses

a subranging architecture to maintain low power con-

sumption at high conversion rates. The output of the

ADC is on an 8-bit databus. The 8-bit databus supports

8x8 output data. ADCCLK samples the input on its

falling edge. After the input is sampled, the MSB (8

upper bits) is latched to the output drivers. On the rising

edge of the ADCCLK, the LSB (8 lower bits) is latched

to the output drivers. The output needs to be

demultiplexed with external circuitry or a digital ASIC.

There is an 8 clock cycle latency (Config 00, 11) or 6

pixel count latency (Config 01, 10) for the analog-to-

digital converter.

The VRT and VRB reference voltages for the ADC are

generated internally, unless the external V is se-

lected. In the external VRT mode, the VRT voltage is set

through the VREF+ pin. This allows the user to select

the dynamic range of the ADC.

Rev. 1.00

▷