An improved instance segmentation algorithm for apple picking robots based on SOLOv2

doi:10.3969/j.issn.1004-1524.20250029

Acta Agriculturae Zhejiangensis ›› 2026, Vol. 38 ›› Issue (3): 588-599.DOI: 10.3969/j.issn.1004-1524.20250029

• Biosystems Engineering • Previous Articles Next Articles

An improved instance segmentation algorithm for apple picking robots based on SOLOv2

ZHANG Guo¹(), ZHOU Qinghui²^,^*(), HE Shengxi³

^1. College of Intelligent Manufacturing and Robotics, Chongqing College of Science and Creation, Chongqing 402160, China
^2. State Key Laboratory of Mechanical Transmission, Chongqing University, Chongqing 400044, China
^3. Chongqing Chang’an Automobile Co., Ltd., Chongqing 400023, China

Received:2025-01-06 Online:2026-03-25 Published:2026-04-17
Contact: ZHOU Qinghui

Abstract

Abstract:

To address the issues prevalent in existing apple instance segmentation algorithms, including variable object scales, susceptibility to background noise which degrades segmentation accuracy, and excessively slow inference speed, an improved SOLOv2-based apple instance segmentation algorithm, termed AE-SOLOv2, is proposed in this paper. First, the StarBlock structure is adopted to optimize the feature extraction network, thereby improving inference efficiency. Subsequently, an enhanced bidirectional feature pyramid network (E-BiFPN) is designed, where additional cross-layer connections facilitate adequate fusion of high-level semantic information and low-level geometric detail information, mitigating the accuracy degradation caused by inconsistent scales of segmentation targets. Furthermore, an attentive feature fusion module is introduced to integrate multi-level and multi-branch feature information. Combined with an adaptive grouping strategy and collaborative processing of global and local features, this module significantly enhances the anti-interference capability of the algorithm against background noise. Experimental results demonstrate that the improved algorithm effectively enhances the instance segmentation precision for apples. On the validation dataset, the mean average precision at an intersection-over-union threshold of 0.5 (mAP₅₀) reaches 91.2%, and the inference time per image is 12.3 ms, which satisfies the real-time requirements for apple instance segmentation. In addition, picking experiments verify that AE-SOLOv2 exhibits superior overall performance even in apple-picking robot scenarios with constrained computational resources, providing a novel solution for the development of agricultural intelligence.

Key words: SOLOv2 network, instance segmentation, picking robot, attention mechanism

CLC Number:

TP391.41
S24

ZHANG Guo, ZHOU Qinghui, HE Shengxi. An improved instance segmentation algorithm for apple picking robots based on SOLOv2[J]. Acta Agriculturae Zhejiangensis, 2026, 38(3): 588-599.

Figures/Tables 12

References 25

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改进点 Improvements	mAP₅₀/%	Params/10⁶	FLOPs/10⁹	t/ms
—	87.3	46.6	179.5	24.7
StarBlock	87.4	21.6	81.9	11.9
StarBlock+E-BiFPN	89.0	21.7	82.4	11.9
StarBlock+	91.2	22.2	83.2	12.3
E-BiFPN+AFFM

改进点 Improvements	mAP₅₀/%	Params/10⁶	FLOPs/10⁹	t/ms
—	87.3	46.6	179.5	24.7
StarBlock	87.4	21.6	81.9	11.9
StarBlock+E-BiFPN	89.0	21.7	82.4	11.9
StarBlock+	91.2	22.2	83.2	12.3
E-BiFPN+AFFM

模型Model	mAP_S/%	mAP_M/%	mAP_L/%	mAP_50:95/%	mAP₅₀/%	mAP₇₅/%	Params/10⁶	FLOPs/10⁹	t/ms
Hybrid Task Cascade	39.0	57.8	80.5	42.5	88.6	58.4	87.6	298.0	59.8
Mask RCNN	38.4	57.9	79.5	42.0	87.5	57.8	63.4	235.0	48.5
Cascade Mask RCNN	38.5	57.7	80.1	42.2	88.0	58.1	77.3	275.0	52.9
YOLACT	38.2	57.0	79.5	41.6	86.7	57.2	35.3	68.4	26.0
RTMDet	37.0	56.3	78.0	40.4	84.1	55.5	10.2	21.6	10.6
SOLOv2	38.3	57.9	79.4	41.9	87.3	57.6	46.6	179.5	24.7
AE-SOLOv2	39.9	59.0	81.5	43.8	91.2	60.2	22.2	83.2	12.3

模型Model	mAP_S/%	mAP_M/%	mAP_L/%	mAP_50:95/%	mAP₅₀/%	mAP₇₅/%	Params/10⁶	FLOPs/10⁹	t/ms
Hybrid Task Cascade	39.0	57.8	80.5	42.5	88.6	58.4	87.6	298.0	59.8
Mask RCNN	38.4	57.9	79.5	42.0	87.5	57.8	63.4	235.0	48.5
Cascade Mask RCNN	38.5	57.7	80.1	42.2	88.0	58.1	77.3	275.0	52.9
YOLACT	38.2	57.0	79.5	41.6	86.7	57.2	35.3	68.4	26.0
RTMDet	37.0	56.3	78.0	40.4	84.1	55.5	10.2	21.6	10.6
SOLOv2	38.3	57.9	79.4	41.9	87.3	57.6	46.6	179.5	24.7
AE-SOLOv2	39.9	59.0	81.5	43.8	91.2	60.2	22.2	83.2	12.3

模型 Model	正确识别数 Correct identifications	漏检数 Missed detections	误检数 False detections	t/ms
SOLOv2	74	10	3	112.4
AE-SOLOv2	80	6	1	58.5

An improved instance segmentation algorithm for apple picking robots based on SOLOv2

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