Researching | Hetero-integrated high-peak-optical-power laser source (940 nm) for time-of-flight sensors

Journals >Chinese Optics Letters >Volume 22 >Issue 7 >Page 072501 > Article

Chinese Optics Letters
Vol. 22, Issue 7, 072501 (2024)

Hetero-integrated high-peak-optical-power laser source (940 nm) for time-of-flight sensors

Sergey Olegovich Slipchenko^1,*, Aleksandr Aleksandrovich Podoskin¹, Ilia Vasil'evich Shushkanov¹, Marina Gennad'evna Rastegaeva¹..., Artem Eduardovich Rizaev¹, Matvey Igorevich Kondratov¹, Artem Evgen'evich Grishin¹, Nikita Aleksandrovich Pikhtin¹, Timur Anatol'evich Bagaev^1,3, Maxim Anatol'evich Ladugin², Aleksandr Anatol'evich Marmalyuk^2,3 and Vladimir Aleksandrovich Simakov²|Show fewer author(s)

Author Affiliations

¹Ioffe Institut, Russian Academy of Sciences, St. Petersburg 194021, Russia

²Open Joint-Stock Company M. F. Stel’makh Polyus Research Institute, Moscow 117342, Russia

³RUDN University, Moscow 117198, Russia

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DOI: 10.3788/COL202422.072501 Cite this Article Set citation alerts

Sergey Olegovich Slipchenko, Aleksandr Aleksandrovich Podoskin, Ilia Vasil'evich Shushkanov, Marina Gennad'evna Rastegaeva, Artem Eduardovich Rizaev, Matvey Igorevich Kondratov, Artem Evgen'evich Grishin, Nikita Aleksandrovich Pikhtin, Timur Anatol'evich Bagaev, Maxim Anatol'evich Ladugin, Aleksandr Anatol'evich Marmalyuk, Vladimir Aleksandrovich Simakov, "Hetero-integrated high-peak-optical-power laser source (940 nm) for time-of-flight sensors," Chin. Opt. Lett. 22, 072501 (2024) Copy Citation Text

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References

[1] S. Royo, M. Ballesta-Garcia. An overview of lidar imaging systems for autonomous vehicles. Appl. Sci., 9, 4093(2019).

[2] R. H. Hadfield, J. Leach, F. Fleming et al. Single-photon detection for long-range imaging and sensing. Optica, 10, 1124(2023).

[3] D. A. Veselov, Y. K. Bobretsova, A. Y. Leshko et al. Measurements of internal optical loss inside an operating laser diode. J. Appl. Phys., 126, 21(2019).

[4] A. Boni, H. Wenzel, P. Crump. Impact of the capture time on power saturation of quantum-well diode lasers. Phys. Scr., 98, 035017(2023).

[5] S. O. Slipchenko, O. S. Soboleva, V. S. Golovin et al. Optimization of cavity parameters of high-power InGaAs/AlGaAs/GaAs laser diodes (λ= 1060 nm) for efficient operation at ultrahigh pulsed pump currents. Bull. Lebedev Phys. Inst., 50, 535(2023).

[6] B. S. Ryvkin, E. A. Avrutin. Spatial hole burning in high-power edge-emitting lasers: a simple analytical model and the effect on laser performance. J. Appl. Phys., 109, 043101(2011).

[7] P. Crump, G. Erbert, H. Wenzel et al. Efficient high-power laser diodes. IEEE J. Sel. Top. Quantum Electron., 19, 1501211(2013).

[8] N. A. Pikhtin, S. O. Slipchenko, Z. N. Sokolova et al. 16 W continuous-wave output power from 100 µm-aperture laser with quantum well asymmetric heterostructure. Electron. Lett., 40, 1413(2004).

[9] A. Knigge, A. Klehr, H. Wenzel et al. Wavelength-stabilized high-pulse-power laser diodes for automotive LiDAR. Phys. Status Solidi A, 215, 1700439(2018).

[10] A. Klehr, A. Liero, H. Christopher et al. Wavelength stabilized high pulse power 48 emitter laser bars for automotive light detection and ranging application. Semicond. Sci. Technol., 35, 065016(2020).

[11] C.-Y. Liu, C.-C. Wu, L.-C. Tang et al. Design of high peak power pulsed laser diode driver. Photonics, 9, 652(2022).

[12] M. Park, Y. Baek, M. Dinare et al. Hetero-integration enables fast switching time-of-flight sensors for light detection and ranging. Sci. Rep., 10, 2764(2020).

[13] I. A. Prudaev, S. N. Vainshtein, M. G. Verkholetov et al. Avalanche delay and dynamic triggering in GaAs-based S-diodes doped with deep level impurity. IEEE Trans. Electron Devices, 68, 57(2020).

[14] S. Vainshtein, G. Duan, T. Rahkonen et al. Self-damping of the relaxation oscillations in miniature pulsed transmitter for sub-nanosecond-precision, long-distance LIDAR. Results Phys., 19, 103509(2020).

[15] V. S. Yuferev, A. A. Podoskin, O. S. Soboleva et al. Specific features of the injection processes dynamics in high-power laser thyristor. IEEE Trans. Electron Devices, 62, 4091(2015).

[16] S. O. Slipchenko, A. A. Podoskin, O. S. Soboleva et al. Generation of nanosecond and subnanosecond laser pulses by AlGaAs/GaAs laser-thyristor with narrow mesa stripe contact. Opt. Express, 24, 16500(2016).

[17] S. O. Slipchenko, D. A. Veselov, V. V. Zolotarev et al. High-power laser diodes based on InGaAs (P)/Al (In) GaAs (P)/GaAs heterostructures with low internal optical loss. Bull. Lebedev Phys. Inst., 50, 494(2023).

[18] S. O. Slipchenko, A. A. Podoskin, V. S. Golovin et al. Near-field dynamics of ultra-wide-aperture (800 µm) diode lasers under nanosecond pulse excitation. IEEE Photon. Technol. Lett., 33, 7(2020).

[19] V. S. Golovin, S. O. Slipchenko, A. A. Podoskin et al. Systematic optimization of QW semiconductor laser design for subnanosecond pulse generation by gain switching. J. Lightwave Technol., 40, 4321(2022).

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Sergey Olegovich Slipchenko, Aleksandr Aleksandrovich Podoskin, Ilia Vasil'evich Shushkanov, Marina Gennad'evna Rastegaeva, Artem Eduardovich Rizaev, Matvey Igorevich Kondratov, Artem Evgen'evich Grishin, Nikita Aleksandrovich Pikhtin, Timur Anatol'evich Bagaev, Maxim Anatol'evich Ladugin, Aleksandr Anatol'evich Marmalyuk, Vladimir Aleksandrovich Simakov, "Hetero-integrated high-peak-optical-power laser source (940 nm) for time-of-flight sensors," Chin. Opt. Lett. 22, 072501 (2024)

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