Saved in:
Bibliographic Details
Main Authors: Layden, Christopher, Juneau, Jill, Pettersson, Gustav, Lourie, Nathan, Schneider, Benjamin, LaMarr, Beverly, Angile, F. Elio, Farag, Fadi, Luo, Michelle, Ong, Zhi Zheng, Furesz, Gabor
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2502.00101
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866909471792431104
author Layden, Christopher
Juneau, Jill
Pettersson, Gustav
Lourie, Nathan
Schneider, Benjamin
LaMarr, Beverly
Angile, F. Elio
Farag, Fadi
Luo, Michelle
Ong, Zhi Zheng
Furesz, Gabor
author_facet Layden, Christopher
Juneau, Jill
Pettersson, Gustav
Lourie, Nathan
Schneider, Benjamin
LaMarr, Beverly
Angile, F. Elio
Farag, Fadi
Luo, Michelle
Ong, Zhi Zheng
Furesz, Gabor
contents The Teledyne COSMOS-66 is a next-generation CMOS camera designed for astronomical imaging, featuring a large-format sensor ($8120 \times 8120$ pixels, each $10 μm$), high quantum efficiency, high frame rates, and a correlated multi-sampling mode that achieves low read noise. We performed a suite of bench-top and on-sky tests to characterize this sensor and analyze its suitability for use in astronomical instruments. This paper presents measurements of linearity, conversion gain, read noise, dark current, quantum efficiency, image lag, and crosstalk. We found that the sensor exhibits nonlinear response below 5% of saturation. This nonlinearity is plausibly attributable to the trapping of electrons in each pixel. We developed and implemented a pixel-by-pixel nonlinearity correction, enabling accurate photometric measurements across the dynamic range. After implementing this correction, operating in the correlated multi-sampling mode, the sensor achieved an effective read noise of $2.9 e^-$ and dark current of $0.12 e^-/pix/s$ at $-25^\circ C$. The quantum efficiency exceeded 50% from 250 nm to 800 nm, peaking at 89% at 600 nm. We observed significant optical crosstalk between the pixels, likely caused by photoelectron diffusion. To demonstrate the sensor's astronomical performance, we mounted it on the WINTER 1m telescope at Palomar Observatory. These tests confirmed that the linearity calibration enables accurate stellar photometry and validated our measured noise levels. Overall, the COSMOS-66 delivers similar noise performance to large-format CCDs, with higher frame rates and relaxed cooling requirements. If pixel design improvements are made to mitigate the nonlinearity and crosstalk, then the camera may combine the advantages of low-noise CMOS image sensors with the integration simplicity of large-format CCDs, broadening its utility to a host of astronomical science cases.
format Preprint
id arxiv_https___arxiv_org_abs_2502_00101
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Characterization of the Teledyne COSMOS Camera: A Large Format CMOS Image Sensor for Astronomy
Layden, Christopher
Juneau, Jill
Pettersson, Gustav
Lourie, Nathan
Schneider, Benjamin
LaMarr, Beverly
Angile, F. Elio
Farag, Fadi
Luo, Michelle
Ong, Zhi Zheng
Furesz, Gabor
Instrumentation and Methods for Astrophysics
The Teledyne COSMOS-66 is a next-generation CMOS camera designed for astronomical imaging, featuring a large-format sensor ($8120 \times 8120$ pixels, each $10 μm$), high quantum efficiency, high frame rates, and a correlated multi-sampling mode that achieves low read noise. We performed a suite of bench-top and on-sky tests to characterize this sensor and analyze its suitability for use in astronomical instruments. This paper presents measurements of linearity, conversion gain, read noise, dark current, quantum efficiency, image lag, and crosstalk. We found that the sensor exhibits nonlinear response below 5% of saturation. This nonlinearity is plausibly attributable to the trapping of electrons in each pixel. We developed and implemented a pixel-by-pixel nonlinearity correction, enabling accurate photometric measurements across the dynamic range. After implementing this correction, operating in the correlated multi-sampling mode, the sensor achieved an effective read noise of $2.9 e^-$ and dark current of $0.12 e^-/pix/s$ at $-25^\circ C$. The quantum efficiency exceeded 50% from 250 nm to 800 nm, peaking at 89% at 600 nm. We observed significant optical crosstalk between the pixels, likely caused by photoelectron diffusion. To demonstrate the sensor's astronomical performance, we mounted it on the WINTER 1m telescope at Palomar Observatory. These tests confirmed that the linearity calibration enables accurate stellar photometry and validated our measured noise levels. Overall, the COSMOS-66 delivers similar noise performance to large-format CCDs, with higher frame rates and relaxed cooling requirements. If pixel design improvements are made to mitigate the nonlinearity and crosstalk, then the camera may combine the advantages of low-noise CMOS image sensors with the integration simplicity of large-format CCDs, broadening its utility to a host of astronomical science cases.
title Characterization of the Teledyne COSMOS Camera: A Large Format CMOS Image Sensor for Astronomy
topic Instrumentation and Methods for Astrophysics
url https://arxiv.org/abs/2502.00101