ICB2FL03G Infineon Technologies, ICB2FL03G Datasheet

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... Infineon Technologies Office. Infineon Technologies components may be used in life-support devices or systems only with the express written approval of Infineon Technologies failure of such components can reasonably be expected to cause the failure of that life-support device or system or to affect the safety or effectiveness of that device or system. Life support devices or systems are intended to be implanted in the human body or to support and/or maintain and sustain and/or protect human life ...

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... Instruments Incorporated. VXWORKS™, WIND RIVER™ of WIND RIVER SYSTEMS, INC. ZETEX™ of Diodes Zetex Limited. Last Trademarks Update 2011-11-11 Preliminary Data Sheet Controller for Fluorescent Lamp Ballasts thJA CIPOS™, CIPURSE™, EconoPACK™, ModSTACK™, my-d™, 3 ICB2FL03G CoolMOS™, CoolSET™, NovalithIC™, OptiMOS™, ORIGA™, V1.1, 2012-04-10 ...

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... Starting the Chip with Accelerated Clock . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36 State Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37 3 3.1 Features during Different Operating Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37 3.2 Operating Flow of the Start-Up Procedure into Run Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38 3.3 Auto Restart and Latched Fault Condition Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39 Preliminary Data Sheet Controller for Fluorescent Lamp Ballasts 4 ICB2FL03G Table of Contents V1.1, 2012-04-10 ...

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... Built-In Customer Test Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53 Application Example . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54 6 6.1 Schematic Ballast 54W T5 Single Lamp . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54 6.2 Bill of Material . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55 6.3 Multi Lamp Ballast Topologies (Series Connection Package Outline . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57 7 7.1 Outline Dimensions of PG-DSO- Preliminary Data Sheet Controller for Fluorescent Lamp Ballasts 5 ICB2FL03G Table of Contents V1.1, 2012-04-10 ...

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... Application Circuit of Ballast for Single Fluorescent Lamp Voltage Mode Preheating . . . . . . . . . . 54 Figure 38 Bill of Material . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55 Figure 39 Application Circuit of Ballast for two Fluorescent Lamps Voltage Mode Preheating . . . . . . . . . . . 56 Figure 40 Package Outline with Creepage Distance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57 Preliminary Data Sheet Controller for Fluorescent Lamp Ballasts 6 ICB2FL03G List of Figures V1.1, 2012-04-10 ...

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... List of Tables Table 1 Pin Configuration for PG-DSO-16- Table 2 Specified Acceleration Factors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36 Table 3 Protection Functions Matrix . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40 Preliminary Data Sheet Controller for Fluorescent Lamp Ballasts 7 ICB2FL03G List of Tables V1.1, 2012-04-10 ...

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... The control concept covers requirements for T5 lamp ballasts for single and multi-lamp designs (series connection supported). ICB2FL03G is based on the 2nd-generation FL controller technology, is easy to use and simple to design in. This makes the ICB2FL03G a basis for cost-effective solutions for fluorescent lamp ballasts with high reliability. ...

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... High side supply voltage High side gate drive (inverter) LSGD 1 16 LSCS 2 15 VCC 3 14 GND 4 13 PFCGD 5 12 PFCCS 6 11 PFCZCD 7 10 PFCVS 8 9 PG-DSO-16 (150mil) 9 ICB2FL03G Pin Configuration and Functionality HSGD HSVCC HSGND RES LVS RTPH RFPH RFRUN V1.1, 2012-04-10 ...

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... CC Preliminary Data Sheet Controller for Fluorescent Lamp Ballasts /dt); the gate voltage typically rises within 245 ns from DRAIN = 2 mA typically). The maximum zener current is internally limited to 5 mA. An (Section 3.3). 10 ICB2FL03G Pin Configuration and Functionality V1.1, 2012-04-10 ...

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... V (109 % of the rated bus voltage) for the detection of overvoltage. The Preliminary Data Sheet Controller for Fluorescent Lamp Ballasts /dt), the gate drive voltage rises within 245 ns from L-level to H-level. The DRAIN 11 ICB2FL03G Pin Configuration and Functionality = 230 V, ACIN V1.1, 2012-04-10 ...

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... Preliminary Data Sheet Controller for Fluorescent Lamp Ballasts Pin Configuration and Functionality ⋅ Ω FRUN f RUN R = RFRUN R ⋅ RFPH f R − PH RFRUN 1 ⋅ Ω eHeating R RTPH ms 100 Ω ICB2FL03G and the resistor PH V1.1, 2012-04-10 ...

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... EOL1 (end-of-life) is assumed. PP has to be below 14.0 V before V cc < V (1.6 V) and the current source is I RES1 13 ICB2FL03G Pin Configuration and Functionality reaches the filament detection level. RES (-21.3 µA) is active as long as RES3 > Such a condition ...

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... R42 R43 C40 R35 Q2 R45 R26 HSGD C17 C15 Q3 C14 R27 LSGD LSCS C16 D6 D7 R30 D8 R25 and Section 2.2.2. Figure run mode (phase 8, Figure = 10.6 V (no IC activity during CC Figure 4). V1.1, 2012-04-10 ICB2FL03G R44 L2 C24 R36 C19 shows the 8 4) and then ...

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... Functional Description 625 ms Mode / Time Mode / Time Mode / Time Run Mode Pre-Run into normal Operation > 14.0 V and before phase 3 is active Figure 4). During the ignition Figure V1.1, 2012-04-10 ICB2FL03G 4), the IC Figure 4). ...

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... Figure 5) phases. The chip supply stage of the IC is protected against overvoltage Figure 1 2 UVLO Monitoring < 160 µA 130 µA - 21.3 µA > 18 µA 16 ICB2FL03G Functional Description 3) and the low current Figure = 160 µA – defines VCC required. Frequency Lamp Voltage 3 4 Start Up Soft Start < ...

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... IC initiates a UVLO RFPH to GND in combination with R21 FPH 3, RFRUN pin). The preheating Figure 3) at pin RTPH from 2500 625ms Normal Operation Pre-Run Run )/ 15steps 127steps. PH RUN V1.1, 2012-04-10 ICB2FL03G ). > RES – the IC waits < 105 %, the = 100 kHz. ...

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... After Ignition Before Ignition 18 Functional Description 3) at pin RFRUN to GND (typically 45 kHz 6). The run mode monitors the Figure 1000 900 800 700 IGNITION 600 500 400 300 200 100 After Pre Heating IGNITION 0 100000 V1.1, 2012-04-10 ICB2FL03G = 40 ms typ Section 2.6). ...

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... PFC Gate Drive 10 Timer t = 100 ms RES Latch Mode 5.0 V 1.6 V Power UP into RUN Mode 1 RES 21.3µA 17.7µA V Lamp 19 ICB2FL03G Functional Description = -21.3 µA. When the voltage at the RES pin Time Time Time Time Time Time Time Time V1.1, 2012-04-10 CC RES ...

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... RES Latch Mode 5.0 V 1.6 V Power UP into RUN Mode 1 RES 21.3µA 17.7µA V Lamp 20 ICB2FL03G Functional Description = - 17.7µA, the controller waits until RES4 = -21.3 µA RES3 = 3.2 V threshold, the RES3 Time Time Time Time Time Time Time Time V1.1, 2012-04-10 ...

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... V is active. The controller prevents a power-up (see RES2 Start UP with OPEN HIGH Side Filament Chip Supply Voltage Start Up Hysteresis No Power UP I RES I LVS 21 ICB2FL03G Functional Description < 14 detected when the current into = 1.6 V. The source current is now set to Time Time Time Time Time V1.1, 2012-04-10 ...

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... Chip Supply Voltage No Power Up Power UP (into RUN Mode) I RES I LVS = -35.4 µA down to I RES2 = 1.3 V, the RES current is set to I RES2 22 ICB2FL03G Functional Description Time Time Time Time Time = -17.7 µA (Figure 13). The controller RES4 = -21.3 µA, and the controller RES3 V1 ...

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... With this control method, the PFC converter Figure 14 (Figure (C11 acts as a spike suppression filter). Figure 3 23 ICB2FL03G Functional Description = 4.0 µs and a ON > 0.5µs. ON Frequency @ CritCM Operation Nominal Load ON Time Hysteresis PRE HEATING ...

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... Preheating Ignition Soft Start 11ms 0 - 2500 237ms BUSrated (Figure 15, phase 3) within 80 ms before entering the soft start phase 4. > 1 pre-run mode LSCS 24 ICB2FL03G Functional Description > 109 %) or open loop BUSrated BUSrated < 109 %. If these BUSrated 7 8 < 109 % / t > 625ms PD V < 105% Fault U BR ...

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... PI Loop Control 75% 95% = 2.5 V (Figure 16). In order to optimize the improved THD (especially in the 17) with the variable PFC ZCD resistor (see resistor R13 in Figure PFCVS 25 ICB2FL03G Functional Description (Figure 16). PWM Gate Drive Over Current 1V ± 5.0% ZCD Start Up 1.5V / 0.5V THD ...

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... PFCCS N ZCD * V BUS N = PFC R ZCD 18) the detection of EOL1 (lamp overvoltage; see 3, Figure 18) is enabled completely. Figure 26 ICB2FL03G Functional Description ZCD @ DC Input Voltage DC Input Voltage 17), the pulse width gate signal is fixed as a 16). This interrupt will restart after the next V1.1, 2012-04-10 ...

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... This AC current is fed into the LVS pins via the network R41, R42, R43 the sensed AC current exceeds 210 µA Figure 2 0 Normal Operation 105µA Peak 2 0 Peak EOL1 Detection 27 ICB2FL03G Functional Description EOL2 EOL1 Rectifier Effect PP Figure EOL1 Lamp Overvoltage ...

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... Preliminary Data Sheet Controller for Fluorescent Lamp Ballasts 20). This current is fed into the LVS pin via the network R41, R42, R43 and 2 0 Normal Operation 0 EOL2 Detection 28 ICB2FL03G Functional Description (Figure 20 LVSDC current) for longer than 4 t EOL2 Rectifier Effect 2500 ms ...

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... RUN Mode IGNITION Frequency [Hz] After Ignition Before Ignition V DSLS I DSLS V GateHS V GateLS V LSCS + CAPLOAD 1 29 ICB2FL03G Functional Description 1000 900 800 700 600 500 400 300 200 100 Pre Heating 0 100000 22). If this status is present Figure Capacitive Load 1 (Idling) 2nd 50% ON Time V1 ...

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... LSCS END of Dead Time Measurement Dead Time START of Dead Time 200 ns Measurement Propagation Delay Stored Dead Time Stored Dead Time 30 ICB2FL03G Functional Description LSCS Capacitive Load 2 (Over Current ) t CAPLOAD 2 Figure drops for longer than typically 200 ns LSCS Dead Time V1.1, 2012-04- ...

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... In that case, the PFC and inverter drivers are immediately Figure Bus Voltage Drop for t < 800 ms Restart without Preheating Interrupt for t < 800 ms Power Down RUN Mode Pre Run Mode < < < 160 µA QGate 31 ICB2FL03G Functional Description Run Mode QGate V1.1, 2012-04-10 ...

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... Power Down Mode < <160 µA I < 160 µA Gate t = 800ms Section 2.8.1.1). A resistor at this pin defines the duration of the preheating phase. 32 ICB2FL03G Functional Description 26), the controller forces an undervoltage Figure Run Mode < Gate 2.8.1. start ignition immediately = 0 Ω kΩ from RTPH V1.1, 2012-04-10 ...

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... Lamp PRE HEATING t = 820 ms when using R = 8.2kOhm RTPH Start UP without Pre Heating CC Chip Supply Voltage Start Up UVLO Hysteresis RTPH Set RTPH Resistor to GND LSGD Lamp INGNITION directly 33 ICB2FL03G Functional Description Figure 28). Time Time Time Time Time Time Time Time V1.1, 2012-04-10 ...

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... Hysteresis Duration is set by Resistor only Preheating t = 820 ms when using RRTPH = 8.2kOhm IGNITION Chip Supply Voltage Start Up UVLO Hysteresis Set by external 5.0V Signal IC remains in Preheating NO Ignition 34 ICB2FL03G Functional Description in Figure PreHeat Time Time Time Time Time Time Time Time V1.1, 2012-04-10 30). ...

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... RES PIN set to GND V LSGD 10V V Lamp V CC 17.5 V 16.0 V Chip Supply Voltage 14.0 V 10.6 V Start Up UVLO V Hysteresis RES 5.0 V LVS PIN set to GND 1 LSGD 10V V Lamp 35 ICB2FL03G Functional Description Time Time Time Time Time Time Time Time Figure 32 V1.1, 2012-04-10 ...

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... V (± – RFRUN RFPH > 3 5.0 V (± – no power- RES RES Accelerated Ign. Time OUT Propagation Accelerated by Factor 2 Delay Pre Heating Accelerated by Factor 4 Pre RUN by Factor 15 Accelerated EOL2 by Factor 60 in Run Mode Time Time Time Time V1.1, 2012-04-10 ICB2FL03G V), see ...

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... Fault: 10.6V < Vcc < 17.5V; I_VCC < 170µA; I_RES= 21.3µA disabled by Lamp Removal or UVLO F= A single Restart is possible after delay of 200ms by internal Timer 37 ICB2FL03G State Diagram 10.6V < Vcc < 17.5V; I_RES= 21.3µA; f= F_RUN 10.6V < Vcc < 17.5V f= F_RUN 10.6V < ...

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... Pre-Run 17,5V> Vcc >10. f_RUN Reduced Monitoring after t_PRERUN= 625ms Run 17.5V> Vcc >10. f_RUN Complete Monitoring 38 ICB2FL03G State Diagram See Timing and Handling of Fault Conditions See Protection Functions Fault 17.5V> Vcc >10.6V Icc < 170µA Gate Drives off ...

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... Counter Skip PH Y Note: Fault Counter reset Power-up after 40s in Run Mode Reset of Flag Skip Gate Drives off Preheat after Ignition 39 ICB2FL03G State Diagram Fault U BUS Voltage BUS Undervoltage (VBUS < 75% during Run Mode for t > 84µs); BUS Overvoltage (VBUS > 109% for t > ...

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... X S 5µ 5µ 625ms F 620µs F 2500ms F 2500ms F 620µs 40 ICB2FL03G Protection Functions Matrix Consequence Prevents power- Power-down, reset failure latch Prevents power-up Prevents power-up X Power down, latched fault mode, 1 restart Keep Gate drives off, re- start after V hysteresis Stops PFC FET until V > ...

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... F 500ns X F 500ns 500ns 200ms A single restart attempt after delay of internal timer 40s Reset of failure latch by UVLO run mode 41 ICB2FL03G Protection Functions Matrix Consequence X Power down, latched fault mode, 1 restart Stops on-time of PFC FET immediately X Activates ignition control X Power down, latched ...

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... V –650 650 HSGND dV /dt –40 40 HSGND V –0.3 18.0 HSVCC V –0 HSGD HSVCC 0.3 I –75 0 HSGDsomax I 0 400 HSGDsimax T –25 150 J 42 ICB2FL03G Electrical Characteristics ) or pin 15 (HSV CC Unit Remarks Internally clamped < 500 ns mA < 100 Power Down Mode V mA < 500 ns mA < 100 Power Down Mode ...

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... R – 240 thJALS – 260 3) – V – 2 ESD_HBM V – 1 ESD_CDM V 2.33 2.43 PFCVS95 43 ICB2FL03G Electrical Characteristics Unit Remarks °C W PG_DSO-16-20 T =25°C amb K/W PG_DSO-16-20 PCB area > 30mmx20mm K/W PG_DSO-16-20 PCB area > 30mmx20mm K/W PG_DSO-16-20 PCB area > 30mmx20mm 2) °C Wave Soldering ° ...

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... RFPH RFRUN F 20 120 RFRUN t 0 2500 RTPH RFRUN R 4 – RFPH RTPH Mains 44 ICB2FL03G Electrical Characteristics Unit Remarks V Referring to HSGND 1) V Referring to GND 25° 125° active mode active mode mA In active mode V µA IC Power Down Mode mA IC active mode kHz µ ...

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... HSVCCqu2 2) V 9.9 10.4 11.0 HSVCCOn 2) V 8.1 8.6 9.3 HSVCCOff 2) V 1.4 1.7 2.0 HSVCCHy GND 45 ICB2FL03G Electrical Characteristics = assumed and the IC HSVCC Unit Test Conditions µ – 0.5V VCC VCCOff µ – 0.5V VCC VCCOn mA V > 2.725V PFCVS µ ...

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... PFCZCDnclp I –0.5 – 5.0 PFCZCDBias I –0.5 – 0.5 PFCZCDBias t 350 500 650 Ringsup ∆ 500 700 900 ZCD 46 ICB2FL03G Electrical Characteristics Unit Test Conditions Pulse width when V PFCCS µ 1.5V PFCCS Unit Test Conditions 2mA PFCZCDSink –2mA PFCZCDSource µ ...

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... PFCON_initial t 18.0 24.0 28.0 PFCON_max t 160 270 370 PFCON_min PFCRep PFCOff 47 ICB2FL03G Electrical Characteristics Unit Test Conditions V ± 1 rated bus voltage µ 2.5V PFCVS Unit Test Conditions µ PFCZCD µs 0.45V < VPFCVS < 2.45V ns µ PFCZCD µ ...

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... V 0.3 1.0 1.5 PFCGDuvlo I – –100 – PFCGDSouce I – 500 – PFCGDSink V 11.0 11.7 12.3 PFCGDHigh V 105 245 405 PFCGDRise PFCGDFall 48 ICB2FL03G Electrical Characteristics Unit Test Conditions 5mA PFCGD 20mA PFCGD -20mA PFCGD -20mA PFCGD -1mA / V PFCGD VCC -5mA / V PFCGD VCC ...

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... LSCSCap1 t – 280 – LSCSCap1 V 1.8 2.0 2.2 LSCSCap2 t – 50 – LSCSCap2 V –70 -50 -27 LSCSCap3 t – 280 – LSCSCap3 I –1.0 – 1.0 LSCSBias 49 ICB2FL03G Electrical Characteristics Unit Test Conditions During Run Mode During Run Mode µ 1.5V LSCS V1.1, 2012-04-10 ...

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... F 121.5 135 148.5 StartUp 13.5 SoftStart V – 2.5 RFRUN RFRUN F – 20 RFRUN1 F – 40 RFRUN2 F – 100 RFRUN3 I – –1000 – 650 RFRUNmax 50 ICB2FL03G Electrical Characteristics Unit Test Conditions 5mA LSGD 20mA LSGD 20mA (Source) LSGD = 20mA CC LSGD 5mA CC LSGD ...

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... RES2 V – 3.2 RES3 I –53.2 –42.6 –32.0 RES1 I –44.2 –35.4 –26.6 RES2 I –26.6 –21.3 – 16.0 RES3 I –22.1 –17.7 –13.3 RES4 51 ICB2FL03G Electrical Characteristics Unit Test Conditions Run Mode RFPH kHz 10kΩ RFPH RFRUN µ RFPH µ 10kΩ ...

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... V 0.05 0.22 0.5 HSGDASD I – –50 – HSGDSource I – 300 – HSGDSink T 140 220 300 HSGDRise HSGDFall 52 ICB2FL03G Electrical Characteristics Unit Test Conditions µ LVS 1) mV µA V > V LVS LVSClamp 300µA LVS µApp I > I EOL 1 LVS LVSEOLpp µA I > I ...

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... Built-in Customer Test Mode - Clock RFPH Acceleration. Decreasing time for the following 1) V 5.0 V RFRUN procedures: Preheating by factor 4 V > 14 Timeout ignition by factor Pre-run by factor 15; EOL by 60 RES 53 ICB2FL03G Electrical Characteristics ms For lamp detection ms For V > 95% BUS µs µ V1.1, 2012-04-10 ...

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... Application Example 6.1 Schematic Ballast 54W T5 Single Lamp Figure 37 Application Circuit of Ballast for Single Fluorescent Lamp Voltage Mode Preheating Preliminary Data Sheet Controller for Fluorescent Lamp Ballasts 54 ICB2FL03G Application Example V1.1, 2012-04-10 ...

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... Bill of Material Figure 38 Bill of Material Preliminary Data Sheet Controller for Fluorescent Lamp Ballasts 55 ICB2FL03G Application Example V1.1, 2012-04-10 ...

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... Multi Lamp Ballast Topologies (Series Connection) 90 ... 270 VAC Figure 39 Application Circuit of Ballast for two Fluorescent Lamps Voltage Mode Preheating Preliminary Data Sheet Controller for Fluorescent Lamp Ballasts PFCZCD HSGD HSVCC PFCGD HSGND PFCVS LSGD PFCCS LSCS 56 ICB2FL03G Application Example V1.1, 2012-04-10 ...

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... Package Outline 7.1 Outline Dimensions of PG-DSO-16 Figure 40 Package Outline with Creepage Distance Preliminary Data Sheet Controller for Fluorescent Lamp Ballasts 57 ICB2FL03G Package Outline V1.1, 2012-04-10 ...

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... Published by Infineon Technologies AG ...