SL1714 Quadrature Downconverter Advance Information Supersedes November 1997 issue 1.7 FEATURES ■ Single chip system for wideband quadrature downconversion ■ Compatible with all standard high IF frequencies 1 16 SL1714 AGC IOUT VEEA IFINB IFIN IVCCA QOUT VEEC VCCB VCODIS VCO B VCO A VEEB PSCAL PSCALB VCCC MP16 AGC IOUT VEEA IFINB IFIN IVCCA QOUT VEEC 1 16 SL1714 C The SL1714 is a quadrature downconverter, intended primarily for application in professional and consumer digital satellite tuners. The device contains all elements necessary, with the exception of external local oscillator tank to form a complete system operating at standard satellite receiver intermediate frequencies. It is intended for use with external carrier recovery. The device includes a low noise RF input amplifier, a reference VCO with prescaler output buffer and In-phase and Quadrature mixers with baseband buffer amplifiers containing AGC gain control. The SL1714 is optimised to drive a dual ADC converter such as the VP216. The SL1714 utilises a standard MP16 plastic package, the SL1714C a power MH16 plastic package. DS4619 - 2.0 April 1998 VCCB VCODIS VCO B VCO A VEEB PSCAL PSCALB VCCC ■ Excellent gain and phase match up to 30MHz baseband ■ High output referred linearity for low distortion and multi channel application MH16 Fig. 1 Pin allocation SL1714 ■ Simple low component application ■ Fully balanced low radiation design with fully integrated quadrature generation APPLICATIONS ■ High operating input sensitivity ■ Data communications systems ■ On-board AGC facility ■ Cable systems ■ On chip oscillator for varactor tuning or SAW resonator operation ■ ESD protection (Normal ESD handling procedures should be observed) ■ Satellite receiver systems ORDERING INFORMATION SL1714/KG/MP1S (Sticks) SL1714/KG/MP1T (Tape and Reel) SL1714C/KG/MH1P (Sticks) SL1714C/KG/MH1Q (Tape and Reel) SL1714 QUICK REFERENCE DATA Characteristic Value Units Input noise figure, DSB 17 dB Maximum conversion gain 48 dB Minimum conversion gain 28 dB IP32T output referred +8 dBV Output clip voltage 1.5 V ± 0.5 dB Phase match up to 15MHz ±1 deg Phase match up to 30MHz ± 1.5 deg Gain flatness up to 30MHz ± 0.5 dB - 96 dBc/Hz Gain match up to 30MHz VCO phase noise, SSB @ 10kHz offset Prescaler division ratio 32 Prescaler output swing 1.6 Vp-p AGC IFIN I OUT AGC IFINB AGC VCODIS 0 deg VCO VCO LO 90 deg Quadrature generator ÷32 Fig. 2 SL1714 block diagram 2 Q OUT PSCAL PSCALB SL1714 FUNCTIONAL DESCRIPTION The SL1714 is a wideband quadrature downconverter, optimised for application in both professional and consumer digital satellite receiver systems and requiring a minimum external component count. It contains all the elements required for construction of a quadrature demodulator, with the exception of tank circuit for the local oscillator. A block diagram is shown in Fig. 2. The SL1714 oscillator can be used with either a varactor tuned tank circuit or with a SAW resonator. Both configurations are described in the Application Notes section of this Data Sheet. A typical digital satellite tuner application from tuner input to data transport stream is shown in Fig. 13. In normal applications the second satellite IF frequency of typically 402.75 or 479.5 MHz is fed from the tuner SAW filter to the RF preamplifier, which is optimised for impedance match and signal handling. The amplifier output signal is then split into two balanced channels to drive the In-phase and Quadrature mixers. The typical RF input impedance is shown in Fig. 3. In-phase and Quadrature LO signals for the mixers are derived from the on board local oscillator, which uses an external varactor tuned resonant network and is optimised for low phase noise. The VCO also drives an on board divide by 32 prescaler whose outputs can be used for driving an external PLL control loop for the VCO, where the PLL loop is contained within the QPSK demodulator, for example the VP305. For optimum performance in the varactor tuned application the VCO should be fully symmetric. The VCO has a disable facility by grounding pin 15, VCODIS; in normal application this pin is pulled to Vcc via a 4K7 resistor. The mixer outputs are fed to balanced baseband AGC amplifier stages, which provide for a minimum of 12 dB of AGC control. The typical AGC characteristic is shown in Fig. 4. These amplifiers then feed a low output impedance true differential to single-ended converter output stage. In normal application the output can be either directly AC coupled to the ADC converter such as the VP216, which will generally have a high input impedance, or to drive an anti alias filter. In this later case the maximum load presented to the SL1714 must not exceed a parallel combination of 1KΩ and 15pF. The typical baseband output impedance is contained in Fig. 5. It is recommended that the device is operated with an output amplitude of 760mV under lock conditions. Under transient conditions the output should not exceed the clipping voltage. Input and output interface circuitry is contained in Fig. 6. The typical key performance numbers at 480 MHz IF, 5V Vcc, 1 KΩ load and 25 deg C ambient are contained in table headed 'QUICK REFERENCE DATA'. With SAWR oscillator application the gain and phase match performance will typically exceed these numbers. 3 SL1714 Marker 1 480MHz +j1 Zreal = 96Ω Zimag = 54Ω +j0.5 +j2 +j0.2 0 0.2 0.5 1 X -j0.2 -j0.5 -j2 START 350 MHz STOP 650 MHz -j1 Fig.3 Typical RF input impedance 4 SL1714 50.00 GAIN (dB) 45.00 40.00 33.00 30.00 25.00 0 1 2 3 4 5 Vagc (V) Fig.4 Typical AGC characteristic j1 +j0.5 +j2 +j0.2 X3 0 X2 0.5 1 0.2 X1 -j0.2 1 1MHz 2 15MHz -j0.5 -j2 3 30MHz -j1 Fig. 5 Typical baseband output impedance 5 SL1714 VCO IFIN IFINB VCO 2x20k Vref IF Input VCO Vcc O/P 55k VCODIS Vref I & Q baseband output VCO disable input Vcc 50k AGC O/P Vref Prescaler outputs AGC input Fig. 6 I/O port peripheral circuitry 6 VR1 1K 1 5V 9 C8 100pF + I C 1 SL1714 C7 100nF IOUT C9 47uF R1 75R C15 10nF L5 4u7 C2 100nF C14 10nF /32 5V R2 4K7 Osc SW1 VCO DISABLE Q Mixer VEEA VEEB VEEC 12 8 3 PSCALB AGC 5 4 IFIN IFINB 11 10 PSCAL L6 4u7 16 VCCA VCCB VCCC I Mixer 6 2 15 7 14 13 C11 220nF 2 1 LK2 12nH L1 C10 220nF LK1 D1 BB811 SK3 I CH O/P 4 3 3p9 C13 3p3 5V C12 4 3 R4 110R T2 BCW31 C21 10nF R11 10K R3 110R T1 BCW31 Fig.7 SL1714 standard evaluation board SK4 Q CH O/P VCODIS QOUT VCOB VCOA 2 5V C6 100pF 4K7 5V C4 C5 100pF 100nF 1 C1 100nF C3 100nF R6 SK1 RF IN R7 680R R5 680R 5V C16 10nF C17 100pF 5V XTAL1 XTAL2 SDA SCL P7 P6 P5 R10 4K7 R9 22K R8 22K C20 47nF DRV CH PUMP Vee RF I/P RF I/P Vcc NC P3 P4 T3 BCW31 16 15 14 13 12 11 10 9 30V CN1 DC POWER 2 3 SP5611 IC2 1 1 2 3 4 5 6 7 8 30V C18 18pF C19 220nF 6 5 4 3 X1 4 MHz 5V SCL5 GND 5V0 SDA5 I2C SK4 SL1714 7 SL1714 SL1714 EVALUATION BOARD VERSION 2.0 19-MAR-97 Fig.8 Fig.9 8 5V IF IN 1 SK1 2 3 CN1 POWER R1 75R C2 100nF C1 100nF R7 680R VR1 1K R5 680R Q Mixer VEEA VEEB VEEC 12 8 3 VCO DISABLE 11 10 PSCAL PSCALB 5V 4K7 R2 15 7 14 13 2 SW1 VCODIS QOUT VCOB VCOA 5 IFIN 4 IFINB /32 SL1714 C8 100nF IOUT Osc IC1 C7 100pF AGC 1 5V C6 100nF Fig.10. SL1714 I & Q downconverter with SAW resonator TP1 5V C5 100pF 16 9 6 VCCA VCCB VCCC I Mixer 5V C4 100nF AGC VOLTS R6 4K7 C3 100pF 5V C9 47uF 4 2 Q CH OUT C11 220nF 4 2 SK3 3 R3 110R L1 15nH R4 110R 2 C13 1nF 3 4 SAW RESONATOR SAW1 5V 1 T2 BCW31 1 LK2 C15 180pF C14 10nF SK2 T1 BCW31 I CH OUT 3 1 LK1 C10 220nF + C12 1nF SL1714 9 SL1714 Fig. 11 Fig. 12 10 SL1714 APPLICATION NOTES These application notes should be read in conjunction with circuit diagrams contained in Fig. 7 and 10, and a recommended front end tuner solution contained in Fig. 12. These boards have been designed to demonstrate performance and to allow for initial evaluation of the SL1714. Varator Tuned Oscillator Refer to Fig. 7 circuit diagram and Figs. 8 and 9PCB layout. This application uses a synthesised VCO with a tuning range of 460 MHz to 500 MHz. The surface mount inductor L1 is 12 nH. The VCO frequency is controlled by the SP5611 synthesiser which is programmed via an I2C bus. The RF input to the synthesiser is from the SL1714 prescaler outputs coupled via RF inductors L3 and L4. For functional checking the VCO can be tuned by physically shorting the base of transistor T3 to ground and then adjusting the +30 volt supply to tune the VCO. Under these conditions, due to the unlocked state of the LO, the board WILL NOT BE representative of locked gain and phase match or phase noise performance. In real applications the VCO control voltage will be provided by the QPSK demodulator circuit, such as the VP305. This circuit provides a line voltage to align the reference LO in the SL1714 in both frequency and phase to the centre of the modulation bandwidth, normally 402.75 or 479.5 MHz. As in all feedback loops the bandwidth of the varactor line must be optimised for the symbol rate of the received modulation. It is recommended for optimum performance that the VCO application is implemented symmetrically, in presented drive and impedance to the VCO ports, as demonstrated in the evaluation schematic and PCB. In the recommended application the varactor diodes are referenced to the VCO port DC bias voltages. This limits the minimum tuning voltage on the varactor line to 3V. If lower tuning voltage is required the tank can be AC coupled to the VCO ports by 390pF capacitor and a DC reference voltage for the varactor diodes applied by centre tapping the tank inductors. NB the varactor diodes require a minimum of 1V reverse bias for correct operation. In real applications the maximum tuning range required for the VCO will be determined by the required lock range of the tuner and the manufacturing tolerance of the tank, assuming the quadrature downconverter section will be alignment free. This tuning range will typically be much smaller than the demonstration board, which will consequently improve the VCO phase noise performance. This application can be ported direct to real system implementations. Normal good RF practice must be applied to the layout implementation. Prescaler Outputs (varactor tuned VCO) The VCO frequency divided by 32 is available at the differential prescaler outputs, pins 10 and 11. These enable the VCO frequency to be synthesised by a PLL frequency synthesiser; on the demo board an SP5611 is used for this function however in a real application this function will be provided by the QPSK demodulator function contained in for example the VP305. It is recommended that the prescaler outputs are loaded symmetrically to balance radiation effects. Saw Resonator Oscillator Refer to Fig. 10 circuit diagram and Figs 11 and 12 PCB layout. In the standard application the oscillator uses a varactor diode tuned tank circuit which allows fine tuning of the oscillator frequency via a voltage control line. This control voltage is usually derived from the QPSK/FEC decoder VP305/VP306. Certain applications do not require this fine tune facility so a fixed frequency application using a SAW resonator has been developed. In this application the frequency of the oscillator is determined by the SAW resonator. The SAW is AC coupled into the VCO pins of the device pins 13 and 14 via 100pF coupling capacitors. The SAW resonator used in this application is a ; Murata Part No SAR479.45MB10X200 Prescaler Outputs (SAWR tuned VCO) The VCO frequency divided by 32 is available at the differential prescaler outputs, pins 10 and 11. Normally these outputs will not be required since the derotation and fine tuning required will be processed by the QPSK demodulator. However these frequencies could be used if required for other system reference frequencies or clocks. If used it is recommended that the prescaler outputs are loaded symmetrically to balance radiation effects. VCO Disable The on-chip oscillator can be disabled by connecting VCODIS, pin 15, to ground and enabled by connecting to Vcc via a 4K7 pull up resistor. AGC The AGC facility can be used to control the conversion gain of the SL1714. On the demonstration boards the conversion gain is adjusted by means of a potentiometer, which is set to 2.5V so giving a conversion gain of 40 dB. The voltage adjustment range for the AGC is approximately 0.5 to 4.5 V. It is important that the AGC voltage minimum does not give a conversion gain of greater than 44dBs otherwise the channel amplitude match may be degraded. In real applications the AGC can be either set at a fixed control voltage or controlled by means of the AGC control signal from the QPSK demodulator dependant on the overall dynamic range requirement of the tuner and it’s gain distribution. 11 SL1714 I & Q baseband outputs I2C Bus connections The SL1714 offers a greatly improved drive capability over the SL1710 and as such is much less sensitive to the load conditions. It is still important however to carefully balance the loads presented to the SL1714 to ensure no differential gain or phase degradation is introduced by the load circuits, which will also include effects due to track striplines etc. For demonstration purposes the output is unsuitable for connection via co-axial cables to standard test equipment, where such equipment is normally 50 Ω or highly capacitive. To overcome this problem the outputs of the SL1714 are therefore buffered through emitter followers which are optimised to drive 50 Ω loads without appreciable degradation in the SL1714 performance. These buffer stages are selectable so enabling the outputs to be loaded directly for interfacing direct with an ADC via a low capacitive link. In most applications the SL1714 will normally interface direct into the ADC converter such as the VP216, which will present a >1 KΩ low capacitive load. The output is optimised for typical drive levels of 760 mVp-p and the onset of clipping is typically > 1.5V p-p. The board is provided with an RJ11 I2C bus connector which feeds directly to the SP5611 synthesiser. This connects to a standard 6-way connector cable which is supplied with the I2C/3-wire bus interface box. Input and Output connections The board is provided with the following connectors: A) IF I/P SMA connector SK1which is AC coupled to the RF input of the SL1714. B) I CH OUT SK2 and Q CH OUT SK3 which provide either a buffered or direct baseband output signal from the SL1714 (depending on which way the links LK1 and LK2 are set). The output buffers should be used when driving 50Ω test equipment or co-axial lines. Links and Switches The board is provided with the following: SL1714 Evaluation Board This board has been created to show the operation of the SL1714 I/Q downconverter. It does not attempt to simulate a real system, since in practice the 479.5MHz IF oscillator on the SL1714 (and the 60MHz clock on the subsequent ADC) would be controlled via the baseband IQ demodulator chip such as the VP305 which follows the dual channel ADC. For simplicity, the VCO is locked using GPS SP5611 synthesiser, controlled via an I2C bus. For full evaluation, 30V and 5V supplies are necessary. Supplies The board must be provided with the following supplies: A) 5V for the SL1714 and SP5611 and 30V for the varactor line. The supply connector is a 3 pin 0.1" pitch pin header. The centre pin of the connector is GND. Outputs driven into hard clipping can exhibit amplitude decline. AGC loops should be designed to take account of this. 12 VCO DISABLE switch This disables the VCO of the SL1714. It does NOT power down the chip. AGC ADJUST potentiometer The potentiometer sets the AGC input voltage of the SL1714 which controls the gain of the chip. TP1 is provided as a means of monitoring the AGC voltage. LK1 and LK2 These are links which may be placed either vertically or horizontally to connect the outputs of the SL1714 either directly or via buffers to the SMA output connectors of the board. If the links are placed vertically 1-2 and 3-4 the outputs are connected directly. If the links are placed horizontally 1-3 and 2-4 the ouputs are connected via buffers. SL1714 Programming of Synthesisers SL1714 Operation A SP5611 synthesiser is used to set the frequency of the SL1714 VCO (480MHz). Since the SL1714 incorporates a divide by 32 the synthesised frequency that the SP5611 must be programmed to is 480/32=15MHz. The SL1714 will mix an IF input with its own local oscillator. This is controlled as above via a SP5611 synthesiser. Normally the VCO will be set to the same frequency as the IF input, and the signal mixed directly down to baseband. Alternatively, a CW RF source may be fed into the input of the SL1714 which is deliberately offset from the VCO. By varying the offset from 0-20MHz and monitoring the I and Q channel baseband outputs, the flatness response of the chip/ output filter can be measured. The SL1714 oscillator may also be disabled by setting the ON-VCO-OFF switch to the OFF position. An AGC voltage adjust pot marked AGC ADJUST is provided, together with a test point. Example a) To program the SL1714 to 480MHz. I2C Byte Hex Code Byte 1 (address) Byte 2 (programmable divider 8 MSBs) C2 00 Byte 3 (programmable divider 8 LSBs) Byte 4 (control data) F0 CE Byte 5 (port data) 00 C2 is the address byte (byte 1). 0F00 is the programmable divider information (bytes 2 and 3). CE is the control data information (byte 4). **Note - the programmable divider information should be set to program 480MHz /32 = 15MHz since the SL1714 provides a divide by 32 prescaler output rather than the VCO carrier frequency. It is not possible to program the VCO to 479.5MHz when using a 7.8125kHz phase comparator frequency. The minimum step size is 7.8125KHz x 8 (RF prescaler inside SP5611) x 32 (SL1714 output prescaler) = 2MHz. If the reference divider is set to 1024 mode (3.90625kHz phase comparator frequency), the minimum step size will be 1MHz. This may be achieved by programming the control byte to CC and modifying the programmable divider information for the new step size. Measurement of Gain and Phase Match. a) Synthesise the required frequency (480MHz is used in the example above). b) Connect an RF signal generator to the input. c)Input a signal which should give an output of approx 0dBm (0.707V p-p), in combination with the appropriate AGC setting. d) Connect a vector voltmeter to the BUFFERED outputs when using 50Ω inputs. When using high impedance probes, the direct outputs may be used. Selection of outputs is via the on board U links. e) CALIBRATE the vector voltmeter and the leads to be used. The calibration should be performed at the chosen baseband frequency and level for maximum accuracy. f) Vary the RF input frequency either side of the LO and note the relative I and Q gain and phase reading. If you experience any difficulties with this board, or require further help, please contact Robert Marsh on 01793 518234 or Fred Herman on 01793 518423 13 SL1714 RF I/P from LNB 950MHz 2.15GHz 0.22MHz 0.7V pk-pk 480MHz IF I/P Filter IF Filter TUNER (SL2015) SL1714 (SL1711) I Q AGC Tank circuit ADC 2x6 bit, 90MS/s (VP216) VCO I/p AGC TANK VCO PLL SYNTH. options (SP5658) (3w bus) (SP5055) (I2C bus) (SP5655) (I2C bus) (SP5659) (I2C bus) AGC Loop/line Filters RF TUNER MODULE Fig.13 Example digital front end architecture Note: All ICs shown in Fig. 12 are available from Mitel Semiconductor. 14 QPSK Demod & FEC (VP305) Data Stream SL1714 ELECTRICAL CHARACTERISTICS Test conditions (unless otherwise stated) Tamb= see note 7, Vee= 0V, Vcc = 4.75 to 5.25 V, Fif = 479.5 MHz, IF bandwidth ± 30 MHz, output amplitude -11dBV These characteristics are guaranteed by either production test or design. They apply within the specified ambient temperature and supply voltage unless otherwise stated. Characteristic Pin Min Supply voltage 6,9,16 4.75 Supply current IF input operating 6,9,16 4, 5 frequency (1) IF input impedance 4, 5 Input return loss 4, 5 Input noise figure, DSB 4, 5 Typ 109 350 350 VCO phase noise, SSB -96 @ 10kHz offset VCO Vcc sensitivity VCO temperature stability Prescaler output swing Prescaler output duty 10, 11 10, 11 V 125 550 mA MHz 1.2 40 1.5 50 Conditions Ω Over specified frequency dB operating range, see Fig. 6. Over specified frequency 19 dB operating range, see Fig. 6. Maximum gain setting 1 dB/dB 550 MHz -85 dBc/Hz application. Varactor tuned, determined 2E3 ppm/V by application. Free running 100 ppm/°C Uncompensated 60 Vp-p % ±1 dB dB For any gain setting 0V to 5V See Fig. 4 See Fig. 4 12 17 Units 5.25 75 Variation in NF with gain setting VCO operation range Max Centre frequency and tuning range determined by cycle AGC Gain, Vagc = +2.5V Temp stability of gain 1 40 Gain, Vagc = +0.5V Gain, Vagc = +VCC -0.5V 1 1 44 32 dB dB AGC range I Q gain match 18 ±0.5 ±1 dB dB See Note 3. I Q phase match I Q phase match ±1 ±1.5 ±2 ±6 deg deg See Note 4. See Note 5. I & Q channel in band ripple I & Q channel in band ripple ±0.3 ±0.5 ±1 ±1 dB dB see Note 3. See Note 4. I Q crosstalk -29 -20 dB See Note 2 and 4 for derivation of cross modulation 15 SL1714 ELECTRICAL CHARACTERISTICS (continued) Test conditions (unless otherwise stated) Tamb= See note 7. Vee= 0V, Vcc = 4.75 to 5.25 V, Fif = 479.5 MHz, IF bandwidth ± 30 MHz, output ampltude -11dBV These characteristics are guaranteed by either production test or design. They apply within the specified ambient temperature and supply voltage unless otherwise stated. Characteristic Pin Min Typ Max Units 20 Ω I & Q baseband output 2,7 8 impedance I & Q baseband output 2, 7 -11 recommended level I & Q baseband output 2, 7 1.5 Conditions See note (5), and Fig. 5. dBV See note( 8) Vp-p See note(6) dBV 2 input carriers at -39 dBV within IF bandwidth of ±30MHz AGC set to give composite clipping level IP32T, output referred +3 +9 output of -11 dBV, IM3 tone within baseband bandwidth IM32T output referred -40 dBc 2 input carriers within IF bandwidth of ±30MHz, AGC set to give composite output of -11 dBV, IM3 tone within All prescaler and other -30 dBc spurs in I & Q baseband output. Power supply rejection baseband bandwidth 0.1 - 100MHz, referred to output amplitude of - 11 dBV. 20 dBc Attenuation Vcc to I & Q outputs, over 0-500KHz Notes: 1. 2. 3. 4. 5. 6. 7. 8. 16 Performance not guaranteed over full specified IF input operating range. I Q crosstalk is determined from the gain and phase match by the following formula. Crosstalk = 20* Log (tan(phase error + Atan (1+amplitude imbalance) -45°)). Over specified gain dynamic range, 1KΩ and 15pF load up to 30MHz baseband. Over specified gain dynamic range, 1KΩ and 15pF load up to 15MHz baseband. Over specified gain dynamic range, 1KΩ and 15pF load up to 30MHz baseband. The device should not be operated beyond the point of output clipping since gain match may be compromised. * Operating temperature range for the SL1714 is 0°C to 70°C. This applies to applications featuring a double sided copper board. For other applications not using such a board, the maximum operating temperature may be reduced. Operating temperature range for the SL1714C is 0° to 85°C. Operation above the recommended IQ output level may result in outputs with harmonic performance degraded. SL1714 ABSOLUTE MAXIMUM RATINGS All voltages are reffered to Vee at 0V Characteristics Min Max Units Supply voltage, Vcc -0.3 7 V 2.5 Vp-p IFFIN &IFINB input voltage IFIN & IFINB input DC offset -0.3 Vcc+0.3 V IOUT & QOUT DC offset -0.3 Vcc+0.3 V AGC DC offset -0.3 Vcc+0.3 V VCO1 & 2 DC offset -0.3 Vcc+0.3 V VCODDIS DC offset -0.3 Vcc+0.3 V PSCAL & PSCALB DC offset -0.3 Vcc+0.3 Storage temperature -55 150 °C Junction temperature 125 °C MP16 package thermal resistance chip to Ambient 81 °C/W MH16 package thermal resistance chip to Ambient 60 °C/W MP16 package thermal resisstance chip to case 28 °C/W Power consumption at 5.25V 656 mW ESD protection 3 kV Conditions Mil std 883 latest revision method 3015 cat 1 17 http://www.mitelsemi.com World Headquarters - Canada Tel: +1 (613) 592 2122 Fax: +1 (613) 592 6909 North America Tel: +1 (770) 486 0194 Fax: +1 (770) 631 8213 Asia/Pacific Tel: +65 333 6193 Fax: +65 333 6192 Europe, Middle East, and Africa (EMEA) Tel: +44 (0) 1793 518528 Fax: +44 (0) 1793 518581 Information relating to products and services furnished herein by Mitel Corporation or its subsidiaries (collectively “Mitel”) is believed to be reliable. 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