# Humanoid robot hands

> Source: https://aiwiki.ai/wiki/humanoid_robot_hands
> Updated: 2026-06-21
> Categories: Humanoid Robots
> From AI Wiki (https://aiwiki.ai), a free encyclopedia of artificial intelligence. Quote with attribution.

**Humanoid robot hands** are dexterous end effectors that replicate the grasping, manipulation, and tactile perception of the human hand, which itself has roughly 27 [degrees of freedom](/wiki/degrees_of_freedom).[8] They are widely regarded as the hardest subsystem in [humanoid robot](/wiki/humanoid_robot) design, because human-like manipulation demands packing many actuators, joints, and touch sensors into a hand-sized volume while controlling them in real time. As of 2026, AI Wiki documents 120 humanoid robots with hand or gripper systems, ranging from simple two-finger grippers to fully dexterous five-finger hands with more than 20 degrees of freedom (DOF) per hand.[1]

The most capable designs now approach human anatomy: [Sanctuary AI](/wiki/sanctuary_ai)'s [Phoenix](/wiki/sanctuary_ai_phoenix) hand has 21 DOF and tactile sensors that detect forces as low as 5 millinewtons, close to the roughly 3-millinewton sensitivity of a human fingertip,[2] while the research-grade Shadow Dexterous Hand provides 24 degrees of freedom and over 100 sensors sampled at up to 1 kHz.[3] The field has advanced rapidly, with several robots now manipulating small objects, operating tools, and performing assembly tasks in real factory settings.

## What is a humanoid robot hand?

A humanoid robot hand is an anthropomorphic end effector mounted on a robot arm to perform the grasping and fine manipulation a human hand would. Its capability is usually summarized by three numbers: the count of degrees of freedom (independently controllable joint motions), the number of fingers, and the density and sensitivity of its tactile and force sensing. A higher DOF count allows more grasp types and in-hand reorientation; richer touch sensing lets the hand modulate grip force and detect slip without vision.

## What are the main types of humanoid robot hands?

Humanoid robot hands generally fall into several categories based on their design philosophy and intended use.

### Dexterous hands

Dexterous hands attempt to replicate the full range of human hand motion, typically featuring five fingers with 10 or more degrees of freedom per hand. These hands can perform precision grasps (picking up small objects between fingertips) and power grasps (wrapping around larger objects). Examples include the [Figure 02](/wiki/figure_02) (16 DOF per hand), [XPENG IRON](/wiki/xpeng_robotics_iron) (22 DOF per hand), and [Phoenix](/wiki/sanctuary_ai_phoenix) (21 DOF per hand).[1]

The main challenge with dexterous hands is controlling all the joints simultaneously while maintaining stable grasps. Most dexterous hands use a combination of tendon-driven mechanisms and direct-drive motors.

### Gripper hands

Gripper-style hands use fewer fingers (typically 2-3) with simpler mechanics. They trade dexterity for reliability, grip strength, and lower cost. Robots like the [Atlas](/wiki/atlas_robot) (3-finger gripper) and [Unitree H1](/wiki/unitree_h1) use this approach.[1] Grippers are well suited for pick-and-place tasks in structured environments.

### Specialized designs

Some robots use unconventional hand designs optimized for specific applications:

- **Ball grippers:** Spherical gripping surfaces for adaptable grasps
- **Interchangeable end effectors:** Modular designs that swap between different tool heads
- **Soft/compliant hands:** Flexible materials that conform to object shapes, improving safety and grasp adaptability
- **Cable-driven hands:** Use cables (tendons) routed through the fingers, allowing actuators to be placed in the forearm for reduced hand size and weight. The [MATRIX-3](/wiki/matrix_robotics_matrix_3) uses this approach with 27 DOF cable-driven hands.[1]
- **Biomimetic hands:** The [Clone Alpha](/wiki/clone_robotics_alpha) uses water-powered artificial muscles to replicate human hand anatomy with 26 DOF per hand.[1]

## Hand type distribution

| Hand type | Number of robots |
|---|---|
| Dexterous | 14 |
| Gripper | 5 |
| 20-dof dexterous hands with tactile sensing | 1 |
| Three-fingered dexterous grippers | 1 |
| Dexterous multi-finger | 1 |
| Ball gripper (no dexterous hands) | 1 |
| Interchangeable | 1 |
| Magic-hand dexterous end effector | 1 |

## Complete comparison

The following table lists all 120 humanoid robots with documented hand specifications, sorted by degrees of freedom per hand.[1]

| Robot | Manufacturer | Hand DOF | Fingers | Grip force (N) | Hand type | Force sensors |
|---|---|---|---|---|---|---|
| [MATRIX-3](/wiki/matrix_robotics_matrix_3) | [Matrix Robotics](/wiki/matrix_robotics) | 27 | 5 | N/A | N/A | N/A |
| [Clone Alpha](/wiki/clone_robotics_alpha) | [Clone Robotics](/wiki/clone_robotics) | 26 | N/A | N/A | N/A | N/A |
| [1X Neo](/wiki/1x_neo) | [1X](/wiki/1x) | 22 | 5 | N/A | Dexterous | Yes |
| [NEO](/wiki/1x_technologies_neo) | [1X Technologies](/wiki/1x_technologies) | 22 | 5 | N/A | N/A | N/A |
| [NEO Gamma](/wiki/1x_technologies_neo_gamma) | [1X Technologies](/wiki/1x_technologies) | 22 | N/A | N/A | N/A | N/A |
| [North](/wiki/sharpa_north) | [Sharpa](/wiki/sharpa) | 22 | N/A | N/A | N/A | Yes |
| [Optimus Gen 3](/wiki/tesla_optimus_gen_3) | [Tesla](/wiki/tesla) | 22 | N/A | N/A | N/A | N/A |
| [Walker S2](/wiki/ubtech_walker_s2) | [UBTECH Robotics](/wiki/ubtech) | 22 | 5 | N/A | N/A | N/A |
| [XPENG IRON](/wiki/xpeng_robotics_iron) | [XPENG Robotics](/wiki/xpeng_robotics) | 22 | 5 | N/A | Dexterous | Yes |
| [Agile One](/wiki/agile_robots_se_agile_one) | [Agile Robots SE](/wiki/agile_robots) | 21 | 5 | N/A | N/A | Yes |
| [Phoenix](/wiki/sanctuary_ai_phoenix) | [Sanctuary AI](/wiki/sanctuary_ai) | 21 | 5 | N/A | Dexterous | Yes |
| [Figure 03](/wiki/figure_03) | [Figure](/wiki/figure_ai) | 20 | 5 | N/A | N/A | N/A |
| [Friday](/wiki/friday) | [Holiday Robotics](/wiki/holiday_robotics) | 20 | N/A | N/A | N/A | N/A |
| [QUANTA X2](/wiki/x_square_robot_quanta_x2) | [X Square Robot](/wiki/x_square_robot) | 20 | 5 | N/A | 20-DoF dexterous hands with tactile sensing | N/A |
| [A2 Ultra](/wiki/agibot_a2_ultra) | [AgiBot](/wiki/agibot) | 19 | N/A | N/A | N/A | N/A |
| [RoBee](/wiki/oversonic_robotics_robee) | [Oversonic Robotics](/wiki/oversonic_robotics) | 18 | 5 | N/A | N/A | N/A |
| [TORA DoubleOne](/wiki/paxini_tora_doubleone) | [PaXini Technology](/wiki/paxini_technology) | 18 | 5 | N/A | N/A | N/A |
| [DexBot](/wiki/boshiac_dexbot) | [BOSHIAC / Harbin Institute of Technology](/wiki/boshiac_harbin_institute_of_technology) | 17 | 5 | N/A | N/A | N/A |
| [Figure 02](/wiki/figure_02) | [Figure](/wiki/figure_ai) | 16 | 5 | N/A | Dexterous | Yes |
| [ALLEX](/wiki/wirobotics_allex) | [WIRobotics](/wiki/wirobotics) | 15 | 5 | 40 | N/A | Yes |
| [Unitree G1](/wiki/unitree_g1) | [Unitree](/wiki/unitree) | 14 | 5 | N/A | Three-fingered dexterous grippers | N/A |
| [Zeus 1](/wiki/pl_universe_zeus_1) | [PL Universe](/wiki/pl_universe) | 14 | N/A | N/A | N/A | N/A |
| [Honda ASIMO](/wiki/honda_asimo) | [Honda](/wiki/honda) | 13 | 5 | N/A | Dexterous | Yes |
| [4NE-1](/wiki/4ne_1) | [NEURA Robotics](/wiki/neura_robotics) | 12 | N/A | N/A | N/A | N/A |
| [Atom Max](/wiki/dobot_atom_max) | [DOBOT Robotics](/wiki/dobot_robotics) | 12 | 5 | N/A | N/A | N/A |
| [GR-2](/wiki/fourier_intelligence_gr_2) | [Fourier Intelligence](/wiki/fourier_intelligence) | 12 | N/A | N/A | N/A | N/A |
| [HIVA Haiwa](/wiki/haier_hiva_haiwa) | [Haier](/wiki/haier) | 12 | 5 | N/A | N/A | N/A |
| [HMND 01 Alpha Bipedal](/wiki/humanoid_hmnd_01_alpha) | [Humanoid](/wiki/humanoid) | 12 | 5 | N/A | N/A | N/A |
| [Motion 2](/wiki/vinmotion_motion_2) | [VinMotion](/wiki/vinmotion) | 12 | 5 | N/A | N/A | N/A |
| [Onero H1](/wiki/switchbot_onero_h1) | [SwitchBot](/wiki/switchbot) | 12 | 5 | N/A | N/A | N/A |
| [PHYBOT C1](/wiki/phybot_c1) | [PHYBOT](/wiki/phybot) | 12 | 5 | N/A | N/A | N/A |
| [Qinglong V3.0](/wiki/openloong_qinglong_v3) | [OpenLoong](/wiki/openloong) | 12 | 5 | N/A | N/A | N/A |
| [RAISE A1](/wiki/agibot_raise_a1) | [Agibot](/wiki/agibot) | 12 | 5 | N/A | N/A | N/A |
| [S1](/wiki/astribot_s1) | [Astribot](/wiki/astribot) | 12 | 5 | N/A | Dexterous | Yes |
| [SkyWalker 2](/wiki/eir_technology_skywalker_2) | [EIR Technology](/wiki/eir_technology) | 12 | 5 | N/A | N/A | N/A |
| [Star1](/wiki/robotera_star1) | [Robotera](/wiki/robotera) | 12 | N/A | N/A | N/A | N/A |
| [T800](/wiki/engineai_t800) | [EngineAI](/wiki/engineai) | 12 | 5 | N/A | N/A | N/A |
| [ToraOne](/wiki/paxini_toraone) | [Paxini](/wiki/paxini) | 12 | N/A | N/A | N/A | N/A |
| [VersaBot VB-1](/wiki/lanxin_robotics_versabot_vb_1) | [Lanxin Robotics](/wiki/lanxin_robotics) | 12 | 5 | N/A | N/A | N/A |
| [AstroD. AD-01](/wiki/infiforce_astrod_ad_01) | [INFIFORCE / ELU.AI](/wiki/infiforce_eluai) | 11 | 5 | N/A | N/A | N/A |
| [Cruzr S2](/wiki/ubtech_cruzr_s2) | [UBTECH Robotics](/wiki/ubtech) | 11 | 5 | N/A | N/A | N/A |
| [Fourier GR-1](/wiki/fourier_intelligence_gr_1) | [Fourier Intelligence](/wiki/fourier_intelligence) | 11 | 5 | N/A | Dexterous | Yes |
| [IGRIS-C](/wiki/igris_c) | [Robros](/wiki/robros) | 11 | N/A | N/A | N/A | N/A |
| [Kepler K2 Bumblebee](/wiki/forerunner_k2_bumblebee) | [Kepler Robotics](/wiki/kepler_robotics) | 11 | 5 | N/A | N/A | N/A |
| [MagicBot Z1](/wiki/magiclab_magicbot_z1) | [MagicLab](/wiki/magiclab) | 11 | 5 | N/A | N/A | N/A |
| [Optimus Gen 2](/wiki/tesla_optimus) | [Tesla](/wiki/tesla) | 11 | 5 | N/A | Dexterous | Yes |
| [Pudu D9](/wiki/pudu_robotics_d9) | [Pudu Robotics](/wiki/pudu_technology) | 11 | N/A | N/A | N/A | N/A |
| [XPENG PX5](/wiki/xpeng_px5) | [XPENG Robotics](/wiki/xpeng_robotics) | 11 | N/A | N/A | N/A | N/A |
| [HMND 01](/wiki/humanoid_ai_hmnd_01) | [Humanoid](/wiki/humanoid) | 10 | 5 | N/A | N/A | N/A |
| [KAPEX](/wiki/lg_kist_kapex) | [LG Electronics & KIST](/wiki/lg_electronics) | 10 | 5 | N/A | N/A | N/A |
| [Kuavo-5](/wiki/leju_robotics_kuavo_5) | [Leju Robot](/wiki/leju_robot) | 10 | 5 | N/A | N/A | N/A |
| [LUS 2](/wiki/lumos_robotics_lus2) | [Lumos Robotics](/wiki/lumos_robotics) | 10 | 5 | N/A | N/A | N/A |
| [LimX Oli](/wiki/limx_dynamics_oli) | [LimX Dynamics](/wiki/limx_dynamics) | 10 | 5 | N/A | N/A | N/A |
| [Moby](/wiki/undercontrol_ai_moby) | [UnderControl AI](/wiki/undercontrol_ai) | 10 | 5 | N/A | N/A | N/A |
| [Moz1](/wiki/spirit_ai_moz1) | [Spirit AI](/wiki/spirit_ai) | 10 | 5 | N/A | N/A | N/A |
| [ORCA](/wiki/cyan_robotics_orca) | [Cyan Robotics](/wiki/cyan_robotics) | 10 | 5 | N/A | N/A | N/A |
| [PR-34D](/wiki/perceptyne_pr_34d) | [Perceptyne](/wiki/perceptyne) | 10 | N/A | N/A | N/A | Yes |
| [QUESTER1](/wiki/agibot_quester1) | [AgiBot](/wiki/agibot) | 10 | 5 | N/A | N/A | N/A |
| [Songxing](/wiki/siasun_songxing) | [Siasun Robot & Automation](/wiki/siasun_robot_automation) | 10 | 5 | N/A | N/A | N/A |
| [Yogi](/wiki/cartwheel_robotics_yogi) | [Cartwheel Robotics](/wiki/cartwheel_robotics) | 10 | 5 | N/A | N/A | N/A |
| [AI Worker](/wiki/robotis_ai_worker) | [ROBOTIS](/wiki/robotis) | 7 | 4 | N/A | N/A | Yes |
| [Adam SP](/wiki/pndbotics_adam_sp) | [PNDbotics](/wiki/pndbotics) | 7 | 5 | N/A | N/A | N/A |
| [Alice](/wiki/aei_robot_alice) | [AEI Robot](/wiki/aei_robot) | 7 | 5 | N/A | N/A | N/A |
| [Maker H01](/wiki/gigaai_maker_h01) | [GigaAI](/wiki/gigaai) | 7 | 5 | N/A | N/A | N/A |
| [Spaceo Pro](/wiki/muks_robotics_spaceo_pro) | [Muks Robotics](/wiki/muks_robotics) | 7 | 5 | N/A | N/A | N/A |
| [THEMIS V2](/wiki/westwood_themis_v2) | [Westwood Robotics](/wiki/westwood_robotics) | 7 | N/A | N/A | N/A | N/A |
| [VB1-I](/wiki/lanxin_robotics_vb1_i) | [Lanxin Robotics](/wiki/lanxin_robotics) | 7 | 5 | N/A | N/A | N/A |
| [VB2](/wiki/lanxin_robotics_vb2) | [Lanxin Robotics](/wiki/lanxin_robotics) | 7 | 5 | N/A | N/A | N/A |
| [FlashBot Arm](/wiki/pudu_flashbot_arm) | [PUDU Technology](/wiki/pudu_technology) | 6 | 5 | N/A | N/A | N/A |
| [Forerunner D1](/wiki/forerunner_d1) | [Kepler Robotics](/wiki/kepler_robotics) | 6 | 5 | N/A | N/A | N/A |
| [Forerunner K1](/wiki/forerunner_k1) | [Kepler Robotics](/wiki/kepler_robotics) | 6 | 5 | N/A | Dexterous | Yes |
| [Forerunner S1](/wiki/forerunner_s1) | [Kepler Robotics](/wiki/kepler_robotics) | 6 | 5 | N/A | N/A | N/A |
| [Galbot G1](/wiki/beijing_galaxy_galbot_g1) | [Beijing Galaxy General Robot](/wiki/beijing_galaxy_robot) | 6 | 5 | N/A | N/A | N/A |
| [Hobbs W1](/wiki/noetix_hobbs_w1) | [Noetix Robotics](/wiki/noetix_robotics) | 6 | 5 | N/A | Dexterous multi-finger | N/A |
| [Keenon XMAN-R1](/wiki/keenon_robotics_xman_r1) | [KEENON Robotics](/wiki/keenon_robotics) | 6 | 5 | N/A | N/A | N/A |
| [LimX CL-1](/wiki/limx_dynamics_cl_1) | [LimX Dynamics](/wiki/limx_dynamics) | 6 | 5 | N/A | N/A | N/A |
| [MH3](/wiki/mirsee_robotics_mh3) | [Mirsee Robotics](/wiki/mirsee_robotics) | 6 | 5 | N/A | N/A | N/A |
| [NAVAI-I3](/wiki/zhejiang_humanoid_navai_i3) | [Zhejiang Humanoid Robot Innovation Center](/wiki/zhejiang_humanoid_robot_innovation_center) | 6 | 5 | N/A | N/A | N/A |
| [PHYBOT M1](/wiki/phybot_m1) | [PHYBOT](/wiki/phybot) | 6 | 5 | N/A | N/A | N/A |
| [DUCO](/wiki/siasun_duco) | [SIASUN](/wiki/siasun) | 5 | 5 | N/A | N/A | N/A |
| [GENE.01](/wiki/generative_bionics_gene_01) | [Generative Bionics](/wiki/generative_bionics) | 5 | 5 | N/A | N/A | N/A |
| [ProWhite](/wiki/pl_universe_prowhite) | [PL-Universe](/wiki/pluniverse) | 5 | N/A | N/A | N/A | N/A |
| [Toyota T-HR3](/wiki/toyota_t_hr3) | [Toyota](/wiki/toyota) | 5 | 5 | N/A | Dexterous | Yes |
| [Vega](/wiki/dexmate_vega) | [Dexmate](/wiki/dexmate) | 5 | 5 | N/A | N/A | Yes |
| [Walker X](/wiki/ubtech_walker_x) | [UBTECH Robotics](/wiki/ubtech) | 5 | 5 | N/A | Dexterous | Yes |
| [Eggie](/wiki/tangible_robots_eggie) | [Tangible Robots](/wiki/tangible_robots) | 3 | 5 | N/A | N/A | N/A |
| [MEMO](/wiki/sunday_robotics_memo) | [Sunday Robotics](/wiki/sunday_robotics) | 3 | 4 | N/A | N/A | N/A |
| [Xiao Tuo](/wiki/topstar_xiao_tuo) | [TOPSTAR Group](/wiki/topstar_group) | 3 | N/A | N/A | N/A | N/A |
| [ALPHA](/wiki/tekntrash_alpha) | [TeknTrash](/wiki/tekntrash) | 2 | 4 | N/A | N/A | N/A |
| [CASIVIBOT](/wiki/casivision_casivibot) | [CasiVision](/wiki/casivision) | 2 | N/A | N/A | N/A | N/A |
| [Kinisi 01](/wiki/kinisi_01) | [Kinisi Robotics](/wiki/kinisi_robotics) | 2 | N/A | N/A | N/A | N/A |
| [Kinisi KR1](/wiki/kinisi_robotics_kr1) | [Kinisi Robotics](/wiki/kinisi_robotics) | 2 | N/A | N/A | N/A | N/A |
| [LG CLOiD](/wiki/lg_electronics_cloid) | [LG Electronics](/wiki/lg_electronics) | 2 | 5 | N/A | N/A | N/A |
| [Mirokai](/wiki/enchanted_tools_mirokai) | [Enchanted Tools](/wiki/enchanted_tools) | 2 | 4 | N/A | N/A | N/A |
| [Steve](/wiki/sulube_steve) | [Sulu.be](/wiki/sulube) | 2 | 5 | N/A | N/A | N/A |
| [AEON](/wiki/hexagon_aeon) | [Hexagon](/wiki/hexagon) | N/A | 5 | N/A | N/A | Yes |
| [AIDOL](/wiki/ai_dynamic_organism_lab_aidol) | [AI Dynamic Organism Lab](/wiki/ai_dynamic_organism_lab) | N/A | 5 | N/A | N/A | N/A |
| [Adam Lite](/wiki/pndbotics_adam_lite) | [PNDbotics](/wiki/pndbotics) | N/A | N/A | N/A | Ball gripper (no dexterous hands) | N/A |
| [AgiBot X1](/wiki/agibot_x1) | [AgiBot](/wiki/agibot) | N/A | 4 | N/A | N/A | N/A |
| [AgiBot X2](/wiki/agibot_x2) | [AgiBot](/wiki/agibot) | N/A | 5 | N/A | N/A | N/A |
| [Agility Digit](/wiki/agility_robotics_digit) | [Agility Robotics](/wiki/agility_robotics) | N/A | N/A | N/A | Gripper | Yes |
| [Ameca](/wiki/engineered_arts_ameca) | [Engineered Arts](/wiki/engineered_arts) | N/A | 5 | N/A | Dexterous | N/A |
| [Apollo](/wiki/apptronik_apollo) | [Apptronik](/wiki/apptronik) | N/A | N/A | N/A | Interchangeable | Yes |
| [Atlas](/wiki/atlas_robot) | [Boston Dynamics](/wiki/boston_dynamics) | N/A | 3 | N/A | Gripper | N/A |
| [DR02](/wiki/deep_robotics_dr02) | [DEEP Robotics](/wiki/deep_robotics) | N/A | 5 | N/A | N/A | N/A |
| [MagicBot G1](/wiki/magiclab_magicbot_g1) | [MagicLab](/wiki/magiclab) | N/A | 5 | N/A | Magic-Hand dexterous end effector | N/A |
| [MenteeBot V3](/wiki/mentee_robotics_menteebot_v3) | [Mentee Robotics](/wiki/mentee_robotics) | N/A | N/A | 30 | N/A | N/A |
| [NAO](/wiki/softbank_robotics_nao) | [SoftBank Robotics](/wiki/softbank_robotics) | N/A | 3 | N/A | Gripper | Yes |
| [Phantom MK1](/wiki/foundation_phantom_mk1) | [Foundation](/wiki/foundation) | N/A | 5 | N/A | N/A | N/A |
| [Robin](/wiki/roboligent_robin) | [Roboligent](/wiki/roboligent) | N/A | 5 | N/A | N/A | N/A |
| [Sophia](/wiki/hanson_robotics) | [Hanson Robotics](/wiki/hanson_robotics) | N/A | 5 | N/A | Dexterous | N/A |
| [Spaceo M1](/wiki/muks_robotics_spaceo_m1) | [Muks Robotics](/wiki/muks_robotics) | N/A | 5 | N/A | N/A | N/A |
| [TALOS](/wiki/pal_robotics_talos) | [PAL Robotics](/wiki/pal_robotics) | N/A | N/A | N/A | Gripper | Yes |
| [TARS](/wiki/tars_robotics_tars) | [TARS Robotics](/wiki/tars_robotics) | N/A | 5 | N/A | N/A | N/A |
| [TM Xplore 1](/wiki/techman_robot_tm_xplore_1) | [Techman Robot](/wiki/techman_robot) | N/A | 5 | N/A | N/A | N/A |
| [Tian Yi 2.0](/wiki/beijing_humanoid_tian_yi_2) | [Beijing Humanoid Robot Innovation Center](/wiki/beijing_humanoid_robot_innovation_center) | N/A | 5 | N/A | N/A | N/A |
| [Unitree H1](/wiki/unitree_h1) | [Unitree](/wiki/unitree) | N/A | N/A | N/A | Gripper | Yes |
| [Unitree H2](/wiki/unitree_h2) | [Unitree](/wiki/unitree) | N/A | 5 | N/A | N/A | Yes |
| [Walker C](/wiki/ubtech_walker_c) | [UBTECH Robotics](/wiki/ubtech) | N/A | 5 | N/A | N/A | N/A |
| [Xiaomi CyberOne](/wiki/xiaomi_cyberone) | [Xiaomi](/wiki/xiaomi) | N/A | 5 | N/A | Dexterous | N/A |

## Rankings

### Most degrees of freedom per hand

| Rank | Robot | Manufacturer | DOF per hand | Notes |
|---|---|---|---|---|
| 1 | [MATRIX-3](/wiki/matrix_robotics_matrix_3) | [Matrix Robotics](/wiki/matrix_robotics) | 27 | 5 fingers |
| 2 | [Clone Alpha](/wiki/clone_robotics_alpha) | [Clone Robotics](/wiki/clone_robotics) | 26 | N/A |
| 3 | [1X Neo](/wiki/1x_neo) | [1X](/wiki/1x) | 22 | 5 fingers, dexterous |
| 4 | [NEO](/wiki/1x_technologies_neo) | [1X Technologies](/wiki/1x_technologies) | 22 | 5 fingers |
| 5 | [NEO Gamma](/wiki/1x_technologies_neo_gamma) | [1X Technologies](/wiki/1x_technologies) | 22 | N/A |
| 6 | [North](/wiki/sharpa_north) | [Sharpa](/wiki/sharpa) | 22 | N/A |
| 7 | [Optimus Gen 3](/wiki/tesla_optimus_gen_3) | [Tesla](/wiki/tesla) | 22 | N/A |
| 8 | [Walker S2](/wiki/ubtech_walker_s2) | [UBTECH Robotics](/wiki/ubtech) | 22 | 5 fingers |
| 9 | [XPENG IRON](/wiki/xpeng_robotics_iron) | [XPENG Robotics](/wiki/xpeng_robotics) | 22 | 5 fingers, dexterous |
| 10 | [Agile One](/wiki/agile_robots_se_agile_one) | [Agile Robots SE](/wiki/agile_robots) | 21 | 5 fingers |
| 11 | [Phoenix](/wiki/sanctuary_ai_phoenix) | [Sanctuary AI](/wiki/sanctuary_ai) | 21 | 5 fingers, dexterous |
| 12 | [Figure 03](/wiki/figure_03) | [Figure](/wiki/figure_ai) | 20 | 5 fingers |
| 13 | [Friday](/wiki/friday) | [Holiday Robotics](/wiki/holiday_robotics) | 20 | N/A |
| 14 | [QUANTA X2](/wiki/x_square_robot_quanta_x2) | [X Square Robot](/wiki/x_square_robot) | 20 | 5 fingers, 20-DoF dexterous hands with tactile sensing |
| 15 | [A2 Ultra](/wiki/agibot_a2_ultra) | [AgiBot](/wiki/agibot) | 19 | N/A |

### Highest grip force

| Rank | Robot | Manufacturer | Grip force (N) |
|---|---|---|---|
| 1 | [ALLEX](/wiki/wirobotics_allex) | [WIRobotics](/wiki/wirobotics) | 40 |
| 2 | [MenteeBot V3](/wiki/mentee_robotics_menteebot_v3) | [Mentee Robotics](/wiki/mentee_robotics) | 30 |

### Five-finger hands

86 robots feature five-finger hands, the closest analog to the human hand.[1] Among these, the most dexterous are:

| Robot | Hand DOF | Grip force (N) | Hand type |
|---|---|---|---|
| [MATRIX-3](/wiki/matrix_robotics_matrix_3) | 27 | N/A | N/A |
| [1X Neo](/wiki/1x_neo) | 22 | N/A | dexterous |
| [NEO](/wiki/1x_technologies_neo) | 22 | N/A | N/A |
| [Walker S2](/wiki/ubtech_walker_s2) | 22 | N/A | N/A |
| [XPENG IRON](/wiki/xpeng_robotics_iron) | 22 | N/A | dexterous |
| [Agile One](/wiki/agile_robots_se_agile_one) | 21 | N/A | N/A |
| [Phoenix](/wiki/sanctuary_ai_phoenix) | 21 | N/A | dexterous |
| [Figure 03](/wiki/figure_03) | 20 | N/A | N/A |
| [QUANTA X2](/wiki/x_square_robot_quanta_x2) | 20 | N/A | 20-DoF dexterous hands with tactile sensing |
| [RoBee](/wiki/oversonic_robotics_robee) | 18 | N/A | N/A |
| [TORA DoubleOne](/wiki/paxini_tora_doubleone) | 18 | N/A | N/A |
| [DexBot](/wiki/boshiac_dexbot) | 17 | N/A | N/A |
| [Figure 02](/wiki/figure_02) | 16 | N/A | dexterous |
| [ALLEX](/wiki/wirobotics_allex) | 15 | 40 | N/A |
| [Unitree G1](/wiki/unitree_g1) | 14 | N/A | Three-fingered dexterous grippers |
| [Honda ASIMO](/wiki/honda_asimo) | 13 | N/A | dexterous |
| [Atom Max](/wiki/dobot_atom_max) | 12 | N/A | N/A |
| [HIVA Haiwa](/wiki/haier_hiva_haiwa) | 12 | N/A | N/A |
| [HMND 01 Alpha Bipedal](/wiki/humanoid_hmnd_01_alpha) | 12 | N/A | N/A |
| [Motion 2](/wiki/vinmotion_motion_2) | 12 | N/A | N/A |

## How do leading dexterous hands compare?

The most-cited 2025-2026 hand designs each took a distinct approach to actuation and touch sensing. Tesla's [Optimus Gen 3](/wiki/tesla_optimus_gen_3) hands use a tendon-driven layout with 22 degrees of freedom across both hands (11 per hand) and 25 actuators per forearm and hand, which Tesla says is roughly a 4.5x increase over Gen 2; the fingertips add force-feedback sensors so the robot can register how hard it is gripping.[4] [Figure](/wiki/figure_ai)'s third-generation [Figure 03](/wiki/figure_03) introduced proprietary fingertip sensors with 3-gram tactile sensitivity, enough to feel the weight of a paperclip, after the company concluded that off-the-shelf tactile sensors could not withstand real-world use.[5] [Sanctuary AI](/wiki/sanctuary_ai)'s [Phoenix](/wiki/sanctuary_ai_phoenix) hand uses hydraulic actuation, which Sanctuary says offers an order of magnitude higher power density than cable and electromechanical systems, with 21 degrees of freedom and 5-millinewton tactile sensitivity that enables blind picking and in-hand reorientation.[2][6]

The Shadow Dexterous Hand from Shadow Robot Company remains a long-standing research benchmark. It provides 24 degrees of freedom (20 actuated), with the thumb contributing 5 DOF, and ships with Pressure Sensor Tactiles in the fingertips as standard; a fully instrumented hand carries 129 sensors, more than 100 of them running at up to 1 kHz.[3]

| Hand | DOF | Actuation | Tactile sensing |
|---|---|---|---|
| Shadow Dexterous Hand | 24 (20 actuated) | Tendon (forearm motors or pneumatics) | Fingertip pressure sensors; up to 129 sensors at 1 kHz[3] |
| [Phoenix](/wiki/sanctuary_ai_phoenix) hand | 21 per hand | Hydraulic | 5 mN sensitivity, in-hand manipulation[2] |
| [Figure 03](/wiki/figure_03) hand | 20 per hand | Tendon/electric | 3-gram fingertip sensitivity, palm camera[5] |
| [Optimus Gen 3](/wiki/tesla_optimus_gen_3) hand | 11 per hand | Tendon, 25 actuators per arm | Force-feedback fingertip sensors[4] |

## External dexterous hand suppliers

While many humanoid robots use captive hands built by the same company that integrates the rest of the body, a parallel ecosystem of standalone dexterous hand suppliers sells hands as components to outside humanoid integrators, research labs, and industrial automation customers. These suppliers do not appear in the per-robot table above because their hands are not tied to a single platform; the same product may ship on multiple unrelated humanoids and inside teleoperation rigs.

As of mid-2026 the leading external suppliers in the high-DOF segment are concentrated in China, with the following representative products.[7]

| Supplier | Product | Year revealed | Active DOF | Total DOF | Palm weight | Whole-hand grasp | Drive |
|---|---|---|---|---|---|---|---|
| [Xynova](/wiki/xynova) | [Flex 1](/wiki/xynova_flex_1) | August 2025 | 20 | 25 | 380 g | More than 30 kg | Pure tendon |
| [Xynova](/wiki/xynova) | [Flex 2](/wiki/xynova_flex_2) | May 13, 2026 | Not separately disclosed | 23 | 400 g | 12 kg (4 kg rated continuous) | Hybrid cable plus direct drive |
| [Wuji Tech](/wiki/wuji_tech) | [Wuji Hand](/wiki/wuji_hand) | September 2025 | 20 | 20 | 580 g (skeleton) | 10 kg (static) | In-hand direct drive |
| [Linkerbot](/wiki/linkerbot) | LinkerHand L30 | 2025 | 22 | 22 | Not published | Not published | Tendon, forearm motors |
| [Inspire Robots](/wiki/inspire_robotics) | RH56 series | 2023 to 2025 | 6 to 12 | 6 to 12 | Not published | Not published | Linkage drive |
| Shadow Robot | Shadow Hand (research) | 2005 | 24 | 24 | About 4 kg with forearm | Not published | Tendon, forearm pneumatics or motors |

These component suppliers have become a structural feature of the humanoid market. The Chinese dexterous hand market shipped more than 30,000 units in 2025, with humanoid-grade hands accounting for an estimated 15,000 units (up from about 2,000 the year before), and forecasts published in early 2026 expect the global market to reach roughly 1.4 million units and about 3 billion US dollars in revenue by 2030.[7] The Xynova Flex 2 in particular drew attention at launch for combining a 23-DOF hybrid drive layout with +/-0.1 mm positional repeatability, 0.05 N force control, and a 400 g palm, on a back-drivable mechanism with multimodal tactile, force, and wrist-camera sensing and a "cerebellum"-style adaptive grasping layer.[10][11][12]

The supplier ecosystem also matters because it shapes the strategic decisions of integrated platform makers. [Xiaomi](/wiki/xiaomi) Strategic Investment, for example, joined Xynova's December 2025 angel round (alongside [CATL](/wiki/catl) Capital, Zhengxuan Investment, Orient Renaissance Capital, SEARI Capital, and the L2F Ray Entrepreneur Fund) and increased its position in the March 2026 Pre-A, even though Xiaomi continues to develop a captive bionic hand for its [CyberOne](/wiki/xiaomi_cyberone) platform.[9][13] Genesis AI's bimanual dexterous demonstration in May 2026 used a Wuji-built variant of the Wuji Hand renamed Genesis Hand 1.0. These cross-cutting investments and partnerships suggest the market is converging on a layered structure in which a small number of component suppliers serve a much larger number of humanoid integrators.

## Key technologies

### How are humanoid robot hands actuated?

Robot hands use several actuation methods:

- **Tendon/cable-driven:** Cables route from actuators in the forearm to the finger joints. This keeps the hand compact and lightweight while allowing high DOF counts. Used by [MATRIX-3](/wiki/matrix_robotics_matrix_3), Tesla [Optimus Gen 3](/wiki/tesla_optimus_gen_3), and many dexterous designs.[4]
- **Direct-drive motors:** Small motors at each joint provide precise, responsive control. Used in many modern dexterous hands.
- **Linkage mechanisms:** Mechanical linkages couple finger joints so fewer motors are needed. Common in gripper designs.
- **Hydraulic actuation:** Pressurized fluid drives the joints. [Sanctuary AI](/wiki/sanctuary_ai) reports that its hydraulic system offers an order of magnitude higher power density than cable and electromechanical-based systems.[6]
- **Artificial muscles:** Pneumatic or hydraulic actuators that mimic biological muscles. The [Clone Alpha](/wiki/clone_robotics_alpha) uses water-powered Myofiber artificial muscles.

### How do robot hands sense touch?

Effective manipulation requires rich sensory feedback:

- **Force/torque sensors:** Measure contact forces for stable grasping. Found in hands from [Figure 02](/wiki/figure_02), [Phoenix](/wiki/sanctuary_ai_phoenix), and others.
- **Tactile sensors:** Distributed pressure sensors on fingertips and palms for detecting object shape and slip. The Shadow Dexterous Hand ships Pressure Sensor Tactiles in every fingertip as standard, and Sanctuary's Phoenix detects forces as low as 5 millinewtons, approaching the roughly 3-millinewton sensitivity of a human fingertip.[2][3]
- **Joint encoders:** Measure finger position for precise control.
- **Camera-based sensing:** Some systems use fingertip or palm cameras for close-range visual feedback. The [Figure 03](/wiki/figure_03) hand carries a camera in the palm.[5]

### How are humanoid hands controlled?

Hand control approaches include:

- **Position control:** Commanding specific joint angles for pre-programmed grasps.
- **Force control:** Regulating grip force to handle fragile objects without damage.
- **[Imitation learning](/wiki/imitation_learning):** Training hand policies from human demonstrations using teleoperation. Tactile feedback lets teleoperated pilots perform touch-driven tasks while generating high-quality training data for autonomous policies.[2]
- **[Reinforcement learning](/wiki/reinforcement_learning):** Learning grasp strategies through trial and error in simulation, then transferring to the real hand.

## What problems remain unsolved?

Several open problems remain in humanoid robot hand design:

- **In-hand manipulation:** Rotating or repositioning objects within the hand without setting them down. Most current hands can grasp objects but have limited ability to reorient them.
- **Durability:** Dexterous hands with many moving parts are prone to mechanical wear, especially tendon-driven systems. Industrial deployment requires hands that survive thousands of hours of operation. Figure cited durability as a top reason for developing its tactile sensors in-house.[5]
- **Cost:** High-DOF dexterous hands with tactile sensing are expensive to manufacture. Reducing cost while maintaining performance is an active area of work.
- **Generalization:** Hands trained on specific objects or tasks often struggle with novel objects. Building hands and controllers that generalize across a wide range of household and industrial objects remains difficult.

## See also

- [Humanoid robot](/wiki/humanoid_robot)
- [Humanoid robots](/wiki/humanoid_robots)
- [Robot manipulation](/wiki/robot_manipulation)
- [Degrees of freedom](/wiki/degrees_of_freedom)
- [Dexterous hand](/wiki/dexterous_hand)
- [Xynova](/wiki/xynova)
- [Xynova Flex 1](/wiki/xynova_flex_1)
- [Xynova Flex 2](/wiki/xynova_flex_2)
- [Wuji Hand](/wiki/wuji_hand)
- [Linkerbot](/wiki/linkerbot)
- [Tendon-driven](/wiki/tendon_driven)
- [Tactile sensor](/wiki/tactile_sensor)
- [Imitation learning](/wiki/imitation_learning)

## References

1. [HumanoidSpecs - Robot Hands Database](https://humanoidspecs.com/hands)
2. "Sanctuary AI integrates tactile sensors into Phoenix general purpose robots." The Robot Report, December 2024. https://www.therobotreport.com/sanctuary-ai-integrates-tactile-sensors-into-phoenix-general-purpose-robots/
3. "Shadow Dexterous Hand." Shadow Robot Company, technical specification, 2025. https://www.shadowrobot.com/dexterous-hand-series/
4. "Tesla Optimus Gen 3 Hands: 22-DoF, 50 Actuators Explained." Basenor, 2026. https://www.basenor.com/blogs/news/tesla-optimus-gen-3-hands-22-dof-50-actuators-explained
5. "Introducing Figure 03." Figure AI, October 2025. https://www.figure.ai/news/introducing-figure-03
6. "Sanctuary AI Demonstrates In-Hand Manipulation Capabilities for Improved General Purpose Robot Dexterity." Sanctuary AI, December 2024. https://www.sanctuary.ai/blog/sanctuary-ai-demonstrates-in-hand-manipulation-capabilities-for-improved-general-purpose-robot-dexterity
7. "From Prototypes to Production: Dexterous Hands Kick Off a Mass-Production Race." Gasgoo Auto News, 2026. https://autonews.gasgoo.com/articles/news/from-prototypes-to-production-dexterous-hands-kick-off-a-mass-production-race-2016425582734970881
8. "Kinematics of human hand and robotics applications." International Journal of Science and Research Archive, 2024. https://ijsra.net/sites/default/files/IJSRA-2024-1441.pdf
9. "Chinese Robotics Startup Xynova Raises Over US$13 Million in Angel Round for High-DOF Dexterous Hands." TMTPost, December 26, 2025. https://en.tmtpost.com/post/7822011
10. "Xynova Flex 2 product page." Xynova official site, 2026. https://www.xynova.com.cn/en
11. "Xynova Flex 2 Robotic Hand." Aihola, May 2026. https://aihola.com/article/xynova-flex-2-robotic-hand
12. RoboHub, X post on Xynova Flex 2, May 13, 2026. https://x.com/XRoboHub/status/2054454926382862838
13. "Led by Top Internet Giant, Xynova Closes Pre-A Round." Gasgoo Auto News, March 20, 2026. https://autonews.gasgoo.com/articles/icv/led-by-top-internet-giant-xynova-closes-pre-a-round-2034985780127100928

