The　ideal　current-independent　metal　transfer　characterized　by　ensured　robust　droplet　detachment　at　a　relatively　small　size　at　any　reasonable　low　current,　which　can　sustain　the　arc,　has　been　successfully　realized　in　the　first　part　of　this　study　by　applying　a　high-power　density　pulsed　fiber　laser　to　irradiate　the　droplet　neck.　The　desired　one-droplet-per-laser　pulse　(ODPP)　mode　was　ensured.　The　droplet　flying　trajectory　deflected　from　the　wire　axial　due　to　the　use　of　a　single　laser.　This　second　part　of　the　study　focuses　on　how　relevant　parameters　influence　the　metal　transfer　behavior,　especially　the　droplet　deflection　that　affects　the　controllability　of　bead　formation.　To　facilitate　the　study,　the　relevant　parameters　were　categorized　into　three　major　types:　laser　positioning,　laser　pulse　waveform,　and　arc　parameters.　A　series　of　experiments　was　conducted　to　examine　their　effects　on　successful　ODPP　transfer　and　deflection　minimization.　In　particular,　the　optimal　laser　incident　point　and　angle　for　most　submissive　droplet　detachment　and　smallest　droplet　deflection　were　first　determined.　Secondly,　the　minimums　of　the　laser　peak　power　and　duration　for　stable　ODPP　were　determined.　Finally,　the　droplet　deflections　under　different　welding　currents　in　the　desirable　low　range,　as　well　as　different　torch　orientations　and　arc　lengths,　were　measured　and　analyzed.