FET BIAS CONTROLLER WITH POLARISATION SWITCH AND TONE DETECTION ISSUE 2 - APRIL 1998 DEVICE DESCRIPTION These devices are unconditionally stable over the full working temperature with the FETs in place, subject to the inclusion of the recommended gate and drain capacitors. These ensure RF stability and minimal injected noise. The ZNBG series of devices are designed to meet the bias requirements of GaAs and HEMT FETs commonly used in satellite receiver LNBs, PMR cellular telephones etc. with a minimum of external components. With the addition of two capacitors and a resistor the devices provide drain voltage and current control for three external grounded source FETs, generating the regulated negative rail required for FET gate biasing whilst operating from a single supply. This negative bias, at -3 volts, can also be used to supply other external circuits. It is possible to use less than the devices full complement of FET bias controls, unused drain and gate connections can be left open circuit without affecting operation of the remaining bias circuits. In order to protect the external FETs the circuits have been designed to ensure that, under any conditions including power up/down transients, the gate drive from the bias circuits cannot exceed the range -3.5V to 1V. Furthermore if the negative rail experiences a fault condition, such as overload or short circuit, the drain supply to the FETs will shut down avoiding excessive current flow. The ZNBG3110/11 includes bias circuits to drive up to three external FETs. A control input to the device selects either one of two FETs as operational, the third FET is p e r m a n e n t l y a ct i v e . T hi s f e a t u r e i s particularly used as an LNB polarisation switch. Also specific to LNB applications is the 22KHz tone detection and logic output feature which is used to enable high and low band frequency switching. The ZNBG3110/11 are available in QSOP20 for the minimum in device size. Device operating temperature is -40 to 70°C to suit a wide range of environmental conditions. Drain current setting of the ZNBG3110/11 is user selectable over the range 0 to 15mA, this is achieved with addition of a single resistor. The series also offers the choice of drain voltage to be set for the FETs, the 3110 gives 2.2 volts drain whilst the 3111 gives 2 volts. FEATURES APPLICATIONS • • • • • • • • • • • • • • ZNBG3110 ZNBG3111 Provides bias for GaAs and HEMT FETs Drives up to three FETs Dynamic FET protection Drain current set by external resistor Regulated negative rail generator requires only 2 external capacitors Choice in drain voltage Wide supply voltage range Polarisation switch for LNBs 22KHz tone detection for band switching Compliant with ASTRA control specifications QSOP surface mount package 4-123 Satellite receiver LNBs Private mobile radio (PMR) Cellular telephones ZNBG3110 ZNBG3111 ABSOLUTE MAXIMUM RATINGS Supply Voltage Supply Current Input Voltage (VPOL) Drain Current (per FET) (set by RCAL) Operating Temperature Storage Temperature Power Dissipation (Tamb= 25°C) QSOP20 500mW -0.6V to 12V 100mA 25V Continuous 0 to 15mA -40 to 70°C -50 to 85°C ELECTRICAL CHARACTERISTICS. TEST CONDITIONS Ω) (Unless otherwise stated):Tamb= 25°C,VCC=5V,ID=10mA (RCAL=33kΩ SYMBOL PARAMETER LIMITS CONDITIONS MIN. VCC Supply Voltage ICC Supply Current ID1 to ID3=0 ID1=0,ID2 to ID3=10mA, VPOL=14V ID2=0,ID1 to ID3=10mA, VPOL=15.5V ID1 to ID3=0, ILB=10mA ID1 to ID3=0, IHB=10mA VSUB Substrate Voltage -3.5 (Internally generated) ISUB=0 ISUB=-200µA Output Noise Drain Voltage Gate Voltage CG=4.7nF, CD=10nF CG=4.7nF, CD=10nF END ENG fO TYP. 5 Oscillator Frequency 10 V 15 35 35 45 45 mA mA mA mA mA -2.5 -2.4 V V 0.02 Vpkpk 0.005 Vpkpk 200 4-124 -3.0 UNITS MAX. 350 800 kHz ZNBG3110 ZNBG3111 SYMBOL PARAMETER LIMITS CONDITIONS MIN. TYP. UNITS MAX. GATE CHARACTERISTICS IGO Output Current Range -30 IDx (mA) VPOL (V) 2000 µA IGOx (µ µA) VG1O VG1L VG1H Output Voltage Gate 1 Off Low High ID1=0 VPOL=14 IGO1=-10 ID1=12 VPOL=15.5 IGO1=-10 ID1=8 VPOL=15.5 IGO1=0 -2.7 -2.7 0.4 -2.4 -2.4 0.75 -2.0 -2.0 1.0 V V V VG2O VG2L VG2H Output Voltage Gate 2 Off Low High ID2=0 VPOL=15.5 IGO2=-10 ID2=12 VPOL=14 IGO2=-10 ID2=8 VPOL=14 IGO2=0 -2.7 -2.7 0.4 -2.4 -2.4 0.75 -2.0 -2.0 1.0 V V V VG3L VG3H Output Voltage Gate 3 Low High ID3=12 ID3=8 -3.5 0.4 -2.9 0.75 -2.0 1.0 V V 8 10 12 mA IGO3=-10 IGO3=0 DRAIN CHARACTERISTICS ID Current DIDV DIDT Current Change with VCC VCC= 5 to 10V with Tj Tj=-40 to +70°C VD1 VD2 VD3 0.2 0.05 %/V %/°C Drain 1 Voltage: High ZNBG3110 ID1=10mA, VPOL=15.5V ID1=10mA, VPOL=15.5V ZNBG3111 2.0 1.8 2.2 2.0 2.4 2.2 V V Drain 2 Voltage: High ZNBG3110 ID2=10mA, VPOL=14V ID2=10mA, VPOL=14V ZNBG3111 2.0 1.8 2.2 2.0 2.4 2.2 V V Drain 3 Voltage: High ZNBG3110 ID3=10mA, VPOL=15.5V ID3=10mA, VPOL=15.5V ZNBG3111 2.0 1.8 2.2 2.0 2.4 2.2 V V DVDV DVDT Voltage Change with VCC VCC= 5 to 10V with Tj Tj=-40 to +70°C IL1 IL2 Leakage Current Drain 1 VD1=0.1V, VPOL=14V VD2=0.1V, VPOL=15.5V Drain 2 0.5 50 4-125 %/V ppm 10 10 µA µA ZNBG3110 ZNBG3111 SYMBOL PARAMETER LIMITS CONDITIONS UNITS MIN. TYP. MAX. TONE DETECTION CHARACTERISTICS IB Filter Amplifier Input Bias Current RF1=150kΩ 0.04 0.15 1.0 µA VOUT Output Voltage 5 RF1=150kΩ 1.75 1.95 2.05 V IOUT Output Current 5 VOUT=1.96V, VFIN=2.1V 400 520 650 µA GV Voltage Gain f=22kHz,VIN=1mV VTH Comparator Threshold Voltage 5 f=0 2.95 46 3.2 dB 3.45 V VLOV Output Stage LOV Volt. Range IL=50mA(LB or HB) -0.5 ILOV LOV Bias Current VLOV=0 0.04 0.15 1.0 µA -2.75 0 -2.5 0.01 V V 6 VCC-1.8 V VLBL LB Output Low VLOV=0 IL=-10µA VLOV=3V IL=0 Enabled Enabled 7 -3.5 -0.01 VLBH LB Output High VLOV=0 IL=10mA VLOV=3V IL=50mA Disabled 6 Disabled 7 -0.025 0 2.9 3.0 0.025 V 3.1 V VHBL HB Output Low VLOV=0 IL=-10µA VLOV=3V IL=0 Enabled 6 Enabled 7 -3.5 -0.01 -2.5 0.01 VHBH HB Output High VLOV=0 IL=10mA VLOV=3V IL=50mA Disabled 6 Disabled 7 -0.025 0 2.9 3.0 -2.75 0 V V 0.025 V 3.1 V POLARITY SWITCH CHARACTERISTICS IPOL Input Current VPOL=25V (Applied via RPOL=10kΩ) 10 VTPOL Threshold Voltage VPOL=25V (Applied via RPOL=10kΩ) TSPOL 14 Switching Speed VPOL=25V (Applied via RPOL=10kΩ) 20 40 14.75 15.5 100 µA V ms NOTES: 1. The negative bias voltages specified are generated on-chip using an internal oscillator. Two external capacitors, CNB and CSUB, of 47nF are required for this purpose. 2. The characteristics are measured using an external reference resistor RCAL of value 33k wired from pins RCAL to ground. 3. Noise voltage is not measured in production. 4. Noise voltage measurement is made with FETs and gate and drain capacitors in place on all outputs. CG, 4.7nF, are connected between gate outputs and ground, CD, 10nF, are connected between drain outputs and ground. 5 . These parameters are lneearly related to VCC 6. These parameters are measured using Test Circuit 1 7. These parameters are measured using Test Circuit 2 4-126 ZNBG3110 ZNBG3111 TEST CIRCUIT 1 V2 Characteristics Type AC source Frequency 22kHz Voltage 350mV p/p enabled 100mV p/p disabled TEST CIRCUIT 2 V2 Characteristics Type AC source Frequency 22kHz Voltage 350mV p/p enabled 100mV p/p disabled 4-127 ZNBG3110 ZNBG3111 TYPICAL CHARACTERISTICS 16 Note:- Operation with loads > 200µA is not guaranteed. Vcc = 5V 14 0.0 12 -0.5 10 -1.0 8 -1.5 6 -2.0 4 -2.5 2 -3.0 Vcc = 5V 6V 8V 10V 0 0 20 40 60 80 100 0 Rcal (k) JFET Drain Current v Rcal 2.4 2.3 2.2 Vcc = 5V 6V 8V 10V 2.1 2.0 2 4 6 8 10 12 14 0.2 0.4 0.6 0.8 External Vsub Load (mA) Vsub v External Load 16 Drain Current (mA) JFET Drain Voltage v Drain Current 4-128 1.0 ZNBG3110 ZNBG3111 TYPICAL CHARACTERISTICS 70 VCC = 5V VLOV = 0V Vcc = 5V 60 4 50 2 40 0 30 -2 20 -4 10 -6 0 -8 100 1k 10k 100k 1M 10M Tamb = 70°C Tamb = 25°C Tamb = -40°C 0 10 Frequency (Hz) 20 30 40 50 Load Current (mA) Open Loop Gain v Frequency LB/HB Offset Voltage v Load Current 2.0 VCC = 5V 180 1.9 150 1.8 120 1.7 90 1.6 60 1.5 30 1.4 0 1.3 Tamb = -40 C Tamb = 25°C Tamb = 70°C VCC = 5V 1.2 100 1k 10k 100k 1M 10M 0 Frequency (Hz) 10 20 30 40 50 Load Current (mA) Open Loop Phase v Frequency LB/HB Dropout Voltage v Load Current 100 1.4 VCC = 5V VCC = 5V VIN=0.1Vpkpk Test Circuit 1 1.2 1.0 Stable region 10 0.8 0.6 Unstable Region 1.0 0.4 0.2 0 0.1 100 1k 10k 100k 1M Frequency (Hz) 10pF 100pF 1nF 10nF 100nF LB/HB Load Capacitance Filter Response Stability Boundary 4-129 1uF ZNBG3110 ZNBG3111 FUNCTIONAL DIAGRAM FUNCTIONAL DESCRIPTION The ZNBG devices provide all the bias requirements for external FETs, including the generation of the negative supply required for gate biasing, from the single supply voltage.The diagram above shows a single stage from the ZNBG series. The ZNBG3110/11 contains 3 such stages. The negative rail generator is common to both devices. The drain voltage of the external FET QN is set by the ZNBG device to its normal operating voltage. This is determined by the on board VD Set reference, for the ZNBG3110 this is nominally 2.2 volts whilst the ZNBG3111 provides nominally 2 volts. The drain current taken by the FET is monitored by the low value resistor ID Sense. The amplifier driving the gate of the FET adjusts the gate voltage of QN so that the drain current taken matches the current called for by an external resistor RCAL. Since the FET is a depletion mode transistor, it is often necessary to drive its gate negative with respect to ground to obtain the required drain current. To provide this capability powered from a single positive supply, the device includes a low current negative supply generator. This generator uses an internal oscillator and two external capacitors, CNB and CSUB. 4-130 ZNBG3110 ZNBG3111 The following schematic shows the function of the VPOL input. Only one of the two external FETs numberd Q1 and Q2 are powered at any one time, their selection is controlled by the input VPOL. This input is designed to be wired to the power input of the LNB via a high value (10k) resistor. With the input voltage of the LNB set at or below 14V, FET Q2 will be enabled. With the input voltage at or above 15.5V, FET Q1 will be enabled. The disabled FET has its gate driven low and its drain terminal is switched open circuit. It is permissible to connect the drain pins D1 and D2 together if required by the application circuit. FET number Q3 is always active regardless of the voltage applied to VPOL. Control Input Switch Function Input Sense Polarisation Select ≤14 volts Vertical FET Q2 ≥ 15.5 volts Horizontal FET Q1 4-131 ZNBG3110 ZNBG3111 For many LNB applications tone detection and band switching is required. The ZNBG3110/11 includes the circuitry necessary to detect the presence of a 22kHz tone modulated on the supply input to the LNB. Referring to the following schematic diagram, the main elements of this detector are an op-amp enabling the construction of a Sallen Key filter, a rectifier/smoother and a comparator. Full control is given over the centre frequency and bandwidth of the filter by the selection of two external resistors and capacitors (one of these resistors, R2, shares the function of overvoltage protection of pin VPOL). The rectifier and comparator circuits utilise no external components. 4-132 ZNBG3110 ZNBG3111 APPLICATIONS CIRCUIT APPLICATIONS INFORMATION The above is a partial application circuit for the ZNBG series showing all external components required for appropriate biasing. The bias circuits are unconditionally stable over the full temperature range with the associated FETs and gate and drain capacitors in circuit. Capacitors CD and CG ensure that residual power supply and substrate generator noise is not allowed to affect other external circuits which may be sensitive to RF interference. They also serve to suppress any potential RF feedthrough between stages via the ZNBG device. These capacitors are required for all stages used. Values of 10nF and 4.7nF respectively are recommended however this is design dependent and any value between 1nF and 100nF could be used. The capacitors CNB and CSUB are an integral part of the ZNBGs negative supply generator. The negative bias voltage is generated on-chip using an internal oscillator. The required value of capacitors CNB and CSUB is 47nF. This generator produces a low current supply of approximately -3 volts. Although this generator is intended purely to bias the external FETs, it can be used to power other external circuits via the CSUB pin. Resistor RCAL sets the drain current at which all external FETs are operated. If any bias control circuit is not required, its related drain and gate connections may be left open circuit without affecting the operation of the remaining bias circuits. The ZNBG devices have been designed to protect the external FETs from adverse operating conditions. With a JFET connected to any bias circuit, the gate output voltage of the bias circuit can not exceed the range -3.5V to 1V under any conditions, including powerup and powerdown transients. Should the negative bias generator be shorted or overloaded so that the drain current of the external FETs can no longer be controlled, the drain supply to FETs is shut down to avoid damage to the FETs by excessive drain current. 4-133 ZNBG3110 ZNBG3111 APPLICATIONS INFORMATION(cont) The following block diagram shows the main section of an LNB designed for use with the Astra series of satellites. The ZNBG3110/11 is the core bias and control element of this circuit. The ZNBG provides the negative rail, FET bias control, polarisation switch control, tone detection and band switching with the minimum of external components. Compared to other discrete component solutions the ZNBG circuit reduces component count and overall size required. Single Universal LNB Block Diagram Tone detection and band switching is provided on the ZNBG3110/11 devices. The following diagrams describes how this feature operates in an LNB and the external components required. The presence or absence of a 22kHz tone applied to pin FIN enables one of two outputs, LB and HB. A tone present enables HB and tone absent enables LB. The LB and HB outputs are designed to be compatible with both MMIC and discrete local oscillator applications, selected by pin LOV. Referring to Figure 1 wiring pin LOV to ground will force LB and HB to switch between -2.6V (disabled) and 0V (enabled). Referring to Figure 2 wiring pin LOV to a positive voltage source (e.g. a potential divider across VCC and ground set to the required oscillator supply voltage, VOSC) will force the LB and HB outputs to provide the required oscillator supply, VOSC, when enabled. Tone Detection Function LOV FIN LB HB LB HB GND 22kHz Disabled Enabled -2.6 volts GND — Enabled Disabled GND -2.6 volts 22kHz Disabled Enabled Note 1 VOSC — Enabled Disabled VOSC Note 1 VOSC Note 1: 0 volts in typical LNB applications but ependent on extenal circuits. 4-134 ZNBG3110 ZNBG3111 Figure 1 LOV grounded Figure 2 LOV connected to VOSC 4-135 ZNBG3110 ZNBG3111 CONNECTION DIAGRAM ORDERING INFORMATION Part Number Package Part Mark ZNBG3110Q20 QSOP20 ZNBG3110 ZNBG3111Q20 QSOP20 ZNBG3111 4-136 ZNBG3110 ZNBG3111 PACKAGE DIMENSIONS A IDENTIFICATION RECESS FOR PIN 1 C B D PIN No.1 K PIN Millimetres Inches MIN MAX MIN MAX A 8.55 8.74 0.337 0.344 B 0.635 C 1.42 1.52 0.056 0.06 D 0.20 0.30 0.008 0.012 E 3.81 3.99 0.15 0.157 F 1.35 1.75 0.053 0.069 G 0.10 0.25 0.004 0.01 J 5.79 6.20 0.228 0.244 K 0° 8° 0° 8° 0.025 NOM Zetex plc. Fields New Road, Chadderton, Oldham, OL9-8NP, United Kingdom. Telephone: (44)161 622 4422 (Sales), (44)161 622 4444 (General Enquiries) Fax: (44)161 622 4420 Zetex GmbH Streitfeldstraße 19 D-81673 München Germany Telefon: (49) 89 45 49 49 0 Fax: (49) 89 45 49 49 49 Zetex Inc. 47 Mall Drive, Unit 4 Commack NY 11725 USA Telephone: (516) 543-7100 Fax: (516) 864-7630 Zetex (Asia) Ltd. 3510 Metroplaza, Tower 2 Hing Fong Road, Kwai Fong, Hong Kong Telephone:(852) 26100 611 Fax: (852) 24250 494 These are supported by agents and distributors in major countries world-wide Zetex plc 1998 Internet:http://www.zetex.com This publication is issued to provide outline information only which (unless agreed by the Company in writing) may not be used, applied or reproduced for any purpose or form part of any order or contract or be regarded as a representation relating to the products or services concerned. The Company reserves the right to alter without notice the specification, design, price or conditions of supply of any product or service. 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