TDA6650TT; TDA6651TT 5 V mixer/oscillator and low noise PLL synthesizer for hybrid terrestrial tuner (digital and analog) Rev. 05 — 10 January 2007 Product data sheet 1. General description The TDA6650TT; TDA6651TT is a programmable 3-band mixer/oscillator and low phase noise PLL synthesizer intended for pure 3-band tuner concepts applied to hybrid (digital and analog) or digital only terrestrial and cable TV reception. Table 1. Different versions are available depending on the target application[1] Application Type version hybrid (analog and digital) TDA6650TT/C3 TDA6651TT/C3 digital only TDA6650TT/C3/S2 TDA6651TT/C3/S2 TDA6651TT/C3/S3 [1] See Table 22 “Characteristics” for differences between TDA6651TT/C3/S2 and TDA6651TT/C3/S3. The device includes three double balanced mixers for low, mid and high bands, three oscillators for the corresponding bands, a switchable IF amplifier, a wideband AGC detector and a low noise PLL synthesizer. The frequencies of the three bands are shown in Table 2. Two pins are available between the mixer output and the IF amplifier input to enable IF filtering for improved signal handling and to improve the adjacent channel rejection. Table 2. Band Recommended band limits in MHz RF input Min Oscillator Max Min Max PAL and DVB-T tuners for hybrid application[1] Low 44.25 157.25 83.15 196.15 Mid 157.25 443.25 196.15 482.15 High 443.25 863.25 482.15 902.15 DVB-T tuners for digital only application[2] Low 47.00 160.00 83.15 196.15 Mid 160.00 446.00 196.15 482.15 High 446.00 866.00 482.15 902.15 [1] RF input frequency is the frequency of the corresponding picture carrier for analog standard. [2] RF input frequency is the frequency of the center of DVB-T channel. The IF amplifier is switchable in order to drive both symmetrical and asymmetrical outputs. When it is used as an asymmetrical amplifier, the IFOUTB pin needs to be connected to the supply voltage VCCA. NXP Semiconductors TDA6650TT; TDA6651TT 5 V mixer/oscillator and low noise PLL synthesizer Five open-drain PMOS ports are included on the IC. Two of them, BS1 and BS2, are also dedicated to the selection of the low, mid and high bands. PMOS port BS5 pin is shared with the ADC. The AGC detector provides a control that can be used in a tuner to set the gain of the RF stage. Six AGC take-over points are available by software. Two programmable AGC time constants are available for search tuning and normal tuner operation. The local oscillator signal is fed to the fractional-N divider. The divided frequency is compared to the comparison frequency into the fast phase detector which drives the charge pump. The loop amplifier is also on-chip, including the high-voltage transistor to drive directly the 33 V tuning voltage without the need to add an external transistor. The comparison frequency is obtained from an on-chip crystal oscillator. The crystal frequency can be output to the XTOUT pin to drive the clock input of a digital demodulation IC. Control data is entered via the I2C-bus; six serial bytes are required to address the device, select the Local Oscillator (LO) frequency, select the step frequency, program the output ports and set the charge pump current or select the ALBC mode, enable or disable the crystal output buffer, select the AGC take-over point and time constant and/or select a specific test mode. A status byte concerning the AGC level detector and the ADC voltage can be read out on the SDA line during a read operation. During a read operation, the loop ‘in-lock’ flag, the power-on reset flag and the automatic loop bandwidth control flag are read. The device has 4 programmable addresses. Each address can be selected by applying a specific voltage to pin AS, enabling the use of multiple devices in the same system. The I2C-bus is fast mode compatible, except for the timing as described in the functional description and is compatible with 5 V, 3.3 V and 2.5 V microcontrollers depending on the voltage applied to pin BVS. 2. Features n Single-chip 5 V mixer/oscillator and low phase noise PLL synthesizer for TV and VCR tuners, dedicated to hybrid (digital and analog) as well as pure digital applications (DVB-T) n Five possible step frequencies to cope with different digital terrestrial TV and analog TV standards n Eight charge pump currents between 40 µA and 600 µA to reach the optimum phase noise performance over the bands n Automatic Loop Bandwidth Control (ALBC) sets the optimum phase noise performance for DVB-T channels n I2C-bus protocol compatible with 2.5 V, 3.3 V and 5 V microcontrollers: u Address + 5 data bytes transmission (I2C-bus write mode) u Address + 1 status byte (I2C-bus read mode) u Four independent I2C-bus addresses. n Five PMOS open-drain ports with 15 mA source capability for band switching and general purpose; one of these ports is combined with a 5-step ADC n Wideband AGC detector for internal tuner AGC: TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 2 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer n n n n n n n n n n u Six programmable take-over points u Two programmable time constants u AGC flag. In-lock flag Crystal frequency output buffer 33 V tuning voltage output Fractional-N programmable divider Balanced mixers with a common emitter input for the low band and for the mid band (each single input) Balanced mixer with a common base input for the high band (balanced input) 2-pin asymmetrical oscillator for the low band 2-pin symmetrical oscillator for the mid band 4-pin symmetrical oscillator for the high band Switched concept IF amplifier with both asymmetrical and symmetrical outputs to drive low impedance or SAW filters i.e. 500 Ω / 40 pF. 3. Applications For all applications, the recommendations given in the latest application note AN10544 must be used. 3.1 Application summary n n n n Digital and analog terrestrial tuners (OFDM, PAL, etc.) Cable tuners (QAM) Digital TV sets Digital set-top boxes. 4. Ordering information Table 3. Ordering information Type number Package Name Description Version TDA6650TT/C3 TSSOP38 plastic thin shrink small outline package; 38 leads; body width 4.4 mm; lead pitch 0.5 mm SOT510-1 TDA6650TT/C3/S2 TDA6651TT/C3 TDA6651TT/C3/S2 TDA6651TT/C3/S3 TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 3 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer 5. Block diagram IFOUTA IFFIL1 VCCA n.c. 21 (18) IFFIL2 6 (33) 26 (13) IFOUTB 7 (32) 28 (11) 27 (12) (30) 9 IF AMP AGC DETECTOR TDA6650TT (TDA6651TT) AGC flag AL0, AL1, AL2 ATC (10) 29 (1) 38 LBIN 4 (35) LOW INPUT BS1 LOW MIXER BS1 MID MIXER BS2 LOW OSCILLATOR (2) 37 (5) 34 MBIN HBIN1 HBIN2 3 (36) MID INPUT BS2 MID OSCILLATOR HIGH INPUT BS1 . BS2 BS1 . BS2 HIGH OSCILLATOR (7) 32 (6) 33 RFGND VCCD 5 (34) (3) 36 24 (15) N [14:0] FRACTIONAL DIVIDER OUTPUT BUFFER R0, R1, R2 LOOP AMP XTAL1 XTAL2 SCL SDA AS BVS LOSCOUT MOSCIN1 (21) 18 HOSCIN1 HOSCOUT1 HOSCOUT2 HOSCIN2 OSCGND XTOUT T0, T1, T2 PHASE COMPARATOR FRACTIONAL CALCULATOR LOSCIN MOSCIN2 (8) 31 HIGH MIXER IFGND (4) 35 (9) 30 1 (38) 2 (37) AGC (17) 22 VT 19 (20) 20 (19) CRYSTAL OSCILLATOR 15 (24) 16 (23) 17 (22) 13 (26) BAND SWITCH OUTPUT PORTS AGC POR ADC 14 (25) 8 (31) CP T0, T1, CP0, CP1, T2 CP2 LOCK DETECTOR I2C-BUS TRANSCEIVER (16) 23 CHARGE PUMP REFERENCE DIVIDER 10 (29) BS5BS1 11 (28) 12 (27) FRACTIONAL SPURIOUS COMPENSATION (14) 25 PLLGND fce723 ADC/ BS5 BS3 BS4 BS1 BS2 The pin numbers in parenthesis represent the TDA6651TT. Fig 1. Block diagram TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 4 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer 6. Pinning information 6.1 Pin description Table 4. Pin description Symbol Pin Description TDA6650TT TDA6651TT HBIN1 1 38 high band RF input 1 HBIN2 2 37 high band RF input 2 MBIN 3 36 mid band RF input LBIN 4 35 low band RF input RFGND 5 34 RF ground IFFIL1 6 33 IF filter output 1 IFFIL2 7 32 IF filter output 2 BS4 8 31 PMOS open-drain output port 4 for general purpose AGC 9 30 AGC output BS3 10 29 PMOS open-drain output port 3 for general purpose BS2 11 28 PMOS open-drain output port 2 to select the mid band BS1 12 27 PMOS open-drain output port 1 to select the low band BVS 13 26 bus voltage selection input ADC/BS5 14 25 ADC input or PMOS open-drain output port 5 for general purpose SCL 15 24 I2C-bus serial clock input SDA 16 23 I2C-bus serial data input and output AS 17 22 I2C-bus address selection input XTOUT 18 21 crystal frequency buffer output XTAL1 19 20 crystal oscillator input 1 XTAL2 20 19 crystal oscillator input 2 n.c 21 18 not connected VT 22 17 tuning voltage output CP 23 16 charge pump output VCCD 24 15 supply voltage for the PLL part PLLGND 25 14 PLL ground VCCA 26 13 supply voltage for the analog part IFOUTB 27 12 IF output B for symmetrical amplifier and asymmetrical IF amplifier switch input IFOUTA 28 11 IF output A IFGND 29 10 IF ground HOSCIN1 30 9 high band oscillator input 1 HOSCOUT1 31 8 high band oscillator output 1 HOSCOUT2 32 7 high band oscillator output 2 HOSCIN2 33 6 high band oscillator input 2 TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 5 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Table 4. Pin description…continued Symbol Pin Description TDA6650TT TDA6651TT MOSCIN1 34 5 mid band oscillator input 1 MOSCIN2 35 4 mid band oscillator input 2 OSCGND 36 3 oscillators ground LOSCOUT 37 2 low band oscillator output LOSCIN 38 1 low band oscillator input 6.2 Pinning HBIN1 1 38 LOSCIN LOSCIN 1 38 HBIN1 HBIN2 2 37 LOSCOUT LOSCOUT 2 37 HBIN2 MBIN 3 36 OSCGND OSCGND 3 36 MBIN LBIN 4 35 MOSCIN2 MOSCIN2 4 35 LBIN RFGND 5 34 MOSCIN1 MOSCIN1 5 34 RFGND IFFIL1 6 33 HOSCIN2 HOSCIN2 6 33 IFFIL1 IFFIL2 7 32 HOSCOUT2 HOSCOUT2 7 32 IFFIL2 BS4 8 31 HOSCOUT1 HOSCOUT1 8 31 BS4 AGC 9 30 HOSCIN1 HOSCIN1 9 BS3 10 TDA6650TT 30 AGC TDA6651TT 29 IFGND IFGND 10 BS2 11 28 IFOUTA IFOUTA 11 28 BS2 BS1 12 27 IFOUTB IFOUTB 12 27 BS1 BVS 13 26 VCCA VCCA 13 26 BVS ADC/BS5 14 25 PLLGND SCL 15 24 VCCD SDA 16 AS 17 XTOUT 18 XTAL1 19 29 BS3 PLLGND 14 25 ADC/BS5 VCCD 15 24 SCL 23 CP CP 16 23 SDA 22 VT VT 17 22 AS 21 n.c. n.c. 18 20 XTAL2 001aac025 Fig 2. Pin configuration TDA6650TT 21 XTOUT XTAL2 19 20 XTAL1 001aac026 Fig 3. Pin configuration TDA6651TT 7. Functional description 7.1 Mixer, Oscillator and PLL (MOPLL) functions Bit BS1 enables the BS1 port, the low band mixer and the low band oscillator. Bit BS2 enables the BS2 port, the mid band mixer and the mid band oscillator. When both BS1 and BS2 bits are logic 0, the high band mixer and the high band oscillator are enabled. The oscillator signal is applied to the fractional-N programmable divider. The divided signal fdiv is fed to the phase comparator where it is compared in both phase and frequency with the comparison frequency fcomp. This frequency is derived from the signal present on the crystal oscillator fxtal and divided in the reference divider. There is a fractional calculator on the chip that generates the data for the fractional divider as well as TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 6 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer the reference divider ratio, depending on the step frequency selected. The crystal oscillator requires a 4 MHz crystal in series with an 18 pF capacitor between pins XTAL1 and XTAL2. The output of the phase comparator drives the charge pump and the loop amplifier section. This amplifier has an on-chip high voltage drive transistor. Pin CP is the output of the charge pump, and pin VT is the pin to drive the tuning voltage to the varicap diodes of the oscillators and the tracking filters. The loop filter has to be connected between pins CP and VT. The spurious signals introduced by the fractional divider are automatically compensated by the spurious compensation block. It is possible to drive the clock input of a digital demodulation IC from pin XTOUT with the 4 MHz signal from the crystal oscillator. This output is also used to output 1⁄2fdiv and fcomp signals in a specific test mode (see Table 9). It is possible to switch off this output, which is recommended when it is not used. For test and alignment purposes, it is also possible to release the tuning voltage output by selecting the sinking mode (see Table 9), and by applying an external voltage on pin VT. In addition to the BS1 and BS2 output ports that are used for the band selection, there are three general purpose ports BS3, BS4 and BS5. All five ports are PMOS open-drain type, each with 15 mA drive capability. The connection for port BS5 and the ADC input is combined on one pin. It is not possible to use the ADC if port BS5 is used. The AGC detector compares the level at the IF amplifier output to a reference level which is selected from 6 different levels via the I2C-bus. The time constant of the AGC can be selected via the I2C-bus to cope with normal operation as well as with search operation. When the output level on pin AGC is higher than the threshold VRMH, then bit AGC = 1. When the output level on pin AGC is lower than the threshold VRML, then bit AGC = 0. Between these two thresholds, bit AGC is not defined. The status of the AGC bit can be read via the I2C-bus according to the read mode as described in Table 15. 7.2 I2C-bus voltage The I2C-bus lines SCL and SDA can be connected to an I2C-bus system tied to 2.5 V, 3.3 V or 5 V. The choice of the bus input threshold voltages is made with pin BVS that can be left open-circuit, connected to the supply voltage or to ground (see Table 5). Table 5. I2C-bus voltage selection Pin BVS connection Bus voltage Logic level LOW HIGH To ground 2.5 V 0 V to 0.75 V 1.75 V to 5.5 V Open-circuit 3.3 V 0 V to 1.0 V 2.3 V to 5.5 V To VCC 5V 0 V to 1.5 V 3.0 V to 5.5 V 7.3 Phase noise, I2C-bus traffic and crosstalk While the TDA6650TT; TDA6651TT is dedicated for hybrid terrestrial applications, the low noise PLL will clean up the noise spectrum of the VCOs close to the carrier to reach noise levels at 1 kHz offset from the carrier compatible with e.g. DVB-T reception. TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 7 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Linked to this noise improvement, some disturbances may become visible while they were not visible because they were hidden into the noise in analog dedicated applications and circuits. This is especially true for disturbances coming from the I2C-bus traffic, whatever this traffic is intended for the MOPLL or for another slave on the bus. To avoid this I2C-bus crosstalk and be able to have a clean noise spectrum, it is necessary to use a bus gate that enables the signal on the bus to drive the MOPLL only when the communication is intended for the tuner part (such a kind of I2C-bus gate is included into the NXP terrestrial channel decoders), and to avoid unnecessary repeated sending of the same information. 8. I2C-bus protocol The TDA6650TT; TDA6651TT is controlled via the two-wire I2C-bus. For programming, there is one device address (7 bits) and the R/W bit for selecting read or write mode. To be able to have more than one MOPLL in an I2C-bus system, one of four possible addresses is selected depending on the voltage applied to address selection pin AS (see Table 8). The TDA6650TT; TDA6651TT fulfils the fast mode I2C-bus, according to the NXP I2C-bus specification, except for the timing as described in Figure 4. The I2C-bus interface is designed in such a way that the pins SCL and SDA can be connected to 5 V, 3.3 V or to 2.5 V pulled-up I2C-bus lines, depending on the voltage applied to pin BVS (see Table 5). 8.1 Write mode; R/W = 0 After the address transmission (first byte), data bytes can be sent to the device (see Table 6). Five data bytes are needed to fully program the TDA6650TT; TDA6651TT. The I2C-bus transceiver has an auto-increment facility that permits programming the device within one single transmission (address + 5 data bytes). The TDA6650TT; TDA6651TT can also be partly programmed on the condition that the first data byte following the address is byte 2 (divider byte 1) or byte 4 (control byte 1). The first bit of the first data byte transmitted indicates whether byte 2 (first bit = 0) or byte 4 (first bit = 1) will follow. Until an I2C-bus STOP condition is sent by the controller, additional data bytes can be entered without the need to re-address the device. The fractional calculator is updated only at the end of the transmission (STOP condition). Each control byte is loaded after the 8th clock pulse of the corresponding control byte. Main divider data are valid only if no new I2C-bus transmission is started (START condition) during the computation period of 50 µs. Both DB1 and DB2 need to be sent to change the main divider ratio. If the value of the ratio selection bits R2, R1 and R0 are changed, the bytes DB1 and DB2 have to be sent in the same transmission. TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 8 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer 50 µs START ADDRESS DIVIDER BYTE BYTE 1 DIVIDER CONTROL CONTROL CONTROL CONTROL STOP BYTE 2 BYTE 1 BYTE 2 BYTE 1 BYTE 2 START I2C-bus transmission dedicated to the MOPLL ADDRESS BYTE I2C-bus transmission dedicated to another IC fce921 Fig 4. Example of I2C-bus transmission frame Table 6. I2C-bus write data format Name Byte Bit Ack MSB[1] LSB Address byte 1 1 1 0 0 0 MA1 MA0 R/W = 0 A Divider byte 1 (DB1) 2 0 N14 N13 N12 N11 N10 N9 N8 A Divider byte 2 (DB2) 3 N7 N6 N5 N4 N3 N2 N1 N0 A Control byte 1 (CB1); see Table 7 4 1 T/A = 1 T2 T1 T0 R2 R1 R0 A 1 T/A = 0 0 0 ATC AL2 AL1 AL0 A Control byte 2 (CB2) 5 CP2 CP1 CP0 BS5 BS4 BS3 BS2 BS1 A [1] MSB is transmitted first. Table 7. Description of write data format bits Bit Description A acknowledge MA1 and MA0 programmable address bits; see Table 8 R/W logic 0 for write mode N14 to N0 programmable LO frequency; N = N14 × 214 + N13 × 213 + N12 × 212 + ... + N1 × 21 + N0 T/A test/AGC bit T/A = 0: the next 6 bits sent are AGC settings T/A = 1: the next 6 bits sent are test and reference divider ratio settings T2, T1 and T0 test bits; see Table 9 R2, R1 and R0 reference divider ratio and programmable frequency step; see Table 10 ATC AGC current setting and time constant; capacitor on pin AGC = 150 nF ATC = 0: AGC current = 220 nA; AGC time constant = 2 s ATC = 1: AGC current = 9 µA; AGC time constant = 50 ms AL2, AL1 and AL0 AGC take-over point bits; see Table 11 CP2, CP1 and CP0 charge pump current; see Table 12 BS5, BS4, BS3, BS2 PMOS ports control bits and BS1 BSn = 0: corresponding port is off, high-impedance state (status at power-on reset) BSn = 1: corresponding port is on; VO = VCC − VDS(sat) TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 9 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer 8.1.1 I2C-bus address selection The device address contains programmable address bits MA1 and MA0, which offer the possibility of having up to four MOPLL ICs in one system. Table 8 gives the relationship between the voltage applied to the AS input and the MA1 and MA0 bits. Table 8. Address selection Voltage applied to pin AS MA1 MA0 0 V to 0.1VCC 0 0 0.2VCC to 0.3VCC or open-circuit 0 1 0.4VCC to 0.6VCC 1 0 0.9VCC to VCC 1 1 8.1.2 XTOUT output buffer and mode setting The crystal frequency can be sent to pin XTOUT and used in the application, for example to drive the clock input of a digital demodulator, saving a quartz crystal in the bill of material. To output fxtal, it is necessary to set T[2:0] to 001. If the output signal on this pin is not used, it is recommended to disable it, by setting T[2:0] to 000. This pin is also used to output 1⁄2fdiv and fcomp in a test mode. At power-on, the XTOUT output buffer is set to on, supplying the fxtal signal. The relation between the signal on pin XTOUT and the setting of the T[2:0] bits is given in Table 9. Table 9. XTOUT buffer status and test modes T2 T1 T0 Pin XTOUT Mode 0 0 0 disabled normal mode with XTOUT buffer off 0 0 1 fxtal (4 MHz) normal mode with XTOUT buffer on 0 1 0 1⁄ f 2 div charge pump off 0 1 1 fxtal (4 MHz) switch ALBC on or off[1] 1 0 0 fcomp test mode test mode 1 0 1 1⁄ f 2 div 1 1 0 fxtal (4 MHz) charge pump sinking current[2] 1 1 1 disabled charge pump sourcing current [1] Automatic Loop Bandwidth Control (ALBC) is disabled at power-on reset. After power-on reset this feature is enabled by setting T[2:0] = 011. To disable again the ALBC, set T[2:0] = 011 again. This test mode acts like a toggle switch, which means each time it is set the status of the ALBC changes. To toggle the ALBC, two consecutive Control byte 1s (CB1), should be sent: one byte with T[2:0] = 011 indicating that ALBC will be switched on or off and one byte programming the test mode to be selected (see Table 30, example of I2C-bus sequence). [2] This is the default mode at power-on reset. This mode disables the tuning voltage. 8.1.3 Step frequency setting The step frequency is set by three bits, giving five steps to cope with different application requirements. The reference divider ratio is automatically set depending on bits R2, R1 and R0. The phase detector works at either 4 MHz, 2 MHz or 1 MHz. Table 10 shows the step frequencies and corresponding reference divider ratios. When the value of bits R2, R1 and R0 are changed, it is necessary to re-send the data bytes DB1 and DB2. TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 10 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Table 10. Reference divider ratio select bits R2 R1 R0 Reference divider Frequency ratio comparison Frequency step 0 0 0 2 2 MHz 62.5 kHz 0 0 1 1 4 MHz 142.86 kHz 0 1 0 1 4 MHz 166.67 kHz 0 1 1 4 1 MHz 50 kHz 1 0 0 1 4 MHz 125 kHz 1 0 1 - - reserved 1 1 0 - - reserved 1 1 1 - - reserved 8.1.4 AGC detector setting The AGC take-over point can be selected out of 6 levels according to Table 11. Table 11. AGC programming AL2 AL1 AL0 0 0 0 [1] 124 dBµV (p-p) 1 [1] 121 dBµV (p-p) 0 [1] 118 dBµV (p-p) 115 dBµV (p-p) 0 0 0 1 Typical take-over point level 0 1 1 [2] 1 0 0 [2] 112 dBµV (p-p) 1 [2] 109 dBµV (p-p) 0 [3] IAGC = 0 A 1 [4] VAGC = 3.5 V 1 0 1 1 1 1 [1] This take-over point is available for both symmetrical and asymmetrical modes. [2] This take-over point is available for asymmetrical mode only. [3] The AGC current sources are disabled. The AGC output goes into a high-impedance state and an external AGC source can be connected in parallel and will not be influenced. [4] The AGC detector is disabled and IAGC = 9 µA. 8.1.5 Charge pump current setting The charge pump current can be chosen from 8 values depending on the value of bits CP2, CP1 and CP0 bits; see Table 12. The programming of the CP bits are not taken into account when ALBC mode is in use. Table 12. Charge pump current CP2 CP1 CP0 Charge pump current number Typical current (absolute value in µA) 0 0 0 1 38 0 0 1 2 54 0 1 0 3 83 0 1 1 4 122 1 0 0 5 163 TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 11 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Table 12. Charge pump current…continued CP2 CP1 CP0 Charge pump current number Typical current (absolute value in µA) 1 0 1 6 254 1 1 0 7 400 1 1 1 8 580 8.1.6 Automatic Loop Bandwidth Control (ALBC) In a PLL controlled VCO in which the PLL reduces phase noise close to the carrier, there is an optimum loop bandwidth corresponding to the minimum integrated phase jitter. This loop bandwidth depends on different parameters like the VCO slope, the loop filter components, the dividing ratio and the gain of the phase detector and charge pump. In order to reach the best phase noise performance it is necessary, especially in a wideband system like a digital tuner, to set the charge pump current to different values depending on the band and frequency used. This is to cope with the variations of the different parameters that set the bandwidth. The selection can be done in the application and requires for each frequency to program not only the divider ratios, but also the band and the best charge pump current. The TDA6650TT; TDA6651TT includes the ALBC feature that automatically sets the band and the charge pump current, provided the IC is used in the DVB-T standard application shown in Figure 27 and 28. This feature is activated by setting bits T[2:0] = 011 after power-on reset. This feature is disabled when the same bits are set again. When ALBC is activated, the output ports BS1, BS2 and BS3 are not programmed by the corresponding BS bits, but are set according to Table 13 and 14. When ALBC is active, bit ALBC = 1. Table 14 summarizes the programming of the band selection and the charge pump current when ALBC is active. Table 13. ALBC settings Bit ALBC BS3 BS2 BS1 Band selected BS2 BS1 0 X 0 0 high see Table 14 follows bit BS3 off off 0 X 0 1 low see Table 14 follows bit BS3 off on 0 X 1 0 mid see Table 14 follows bit BS3 on off 0 X 1 1 forbidden 1 X X X depends on LO program, shown in Table 14 Table 14. ALBC band selection and charge current setting LO frequency Band Charge pump current number 80 MHz to 92 MHz low 2 92 MHz to 144 MHz low 3 144 MHz to 156 MHz low 4 156 MHz to 176 MHz low 5 176 MHz to 184 MHz low 6 TDA6650TT_6651TT_5 Product data sheet Charge pump Port current BS3 © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 12 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Table 14. ALBC band selection and charge current setting…continued LO frequency Band Charge pump current number 184 MHz to 196 MHz low 7 196 MHz to 224 MHz mid 2 224 MHz to 296 MHz mid 3 296 MHz to 380 MHz mid 4 380 MHz to 404 MHz mid 5 404 MHz to 448 MHz mid 6 448 MHz to 472 MHz mid 7 472 MHz to 484 MHz mid 8 484 MHz to 604 MHz high 4 604 MHz to 676 MHz high 5 676 MHz to 752 MHz high 6 752 MHz to 868 MHz high 7 868 MHz to 904 MHz high 8 8.2 Read mode; R/W = 1 Data can be read from the device by setting the R/W bit to 1 (see Table 15). After the device address has been recognized, the device generates an acknowledge pulse and the first data byte (status byte) is transferred on the SDA line (MSB first). Data is valid on the SDA line during a HIGH level of the SCL clock signal. A second data byte can be read from the device if the microcontroller generates an acknowledge on the SDA line (master acknowledge). End of transmission will occur if no master acknowledge occurs. The device will then release the data line to allow the microcontroller to generate a STOP condition. Table 15. Name I2C-bus read data format Byte Bit ACK MSB[1] LSB Address byte 1 1 1 0 0 0 MA1 MA0 R/W = 1 A Status byte POR FL ALBC 1 AGC A2 A1 A0 [1] 2 - MSB is transmitted first. Table 16. Description of read data format bits Bit Description A acknowledge bit POR power-on reset flag POR = 0, normal operation POR = 1, power-on reset FL in-lock flag FL = 0, not locked FL = 1, the PLL is locked TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 13 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Table 16. Description of read data format bits…continued Bit Description ALBC automatic loop bandwidth control flag ALBC = 0, no automatic loop bandwidth control ALBC = 1, automatic loop bandwidth control selected AGC internal AGC flag AGC = 0 when internal AGC is active (VAGC < VRML) AGC = 1 when internal AGC is not active (VAGC > VRMH) digital outputs of the 5-level ADC; see Table 17 A2, A1, A0 Table 17. ADC levels Voltage applied to pin ADC[1] A2 A1 A0 0.6VCC to VCC 1 0 0 0.45VCC to 0.6VCC 0 1 1 0.3VCC to 0.45VCC 0 1 0 0.15VCC to 0.3VCC 0 0 1 0 V to 0.15VCC 0 0 0 [1] Accuracy is ±0.03VCC. Bit BS5 must be set to logic 0 to disable the BS5 output port. The BS5 output port uses the same pin as the ADC and can not be used when the ADC is in use. 8.3 Status at power-on reset At power on or when the supply voltage drops below approximately 2.85 V (at Tamb = 25 °C), internal registers are set according to Table 18. At power on, the charge pump current is set to 580 µA, the test bits T[2:0] are set to 110 which means that the charge pump is sinking current, the tuning voltage output is disabled and the ALBC function is disabled. The XTOUT buffer is on, driving the 4 MHz signal from the crystal oscillator and all the ports are off. As a consequence, the high band is selected by default. Table 18. Default setting at power-on reset Name Byte Bit[1] MSB LSB Address byte 1 1 1 0 0 0 MA1 MA0 X Divider byte 1 (DB1) 2 0 N14 = X N13 = X N12 = X N11 = X N10 = X N9 = X N8 = X Divider byte 2 (DB2) 3 N7 = X N6 = X Control byte 1 (CB1) Control byte 2 (CB2) 4 5 N5 = X N4 = X N3 = X N2 = X N1 = X N0 = X T/A = X[2] T2 = 1 T1 = 1 T0 = 0 R2 = X R1 = X R0 = X 1 T/A = X[3] 0 0 ATC = 0 AL2 = 0 AL1 = 1 AL0 = 0 CP2 = 1 CP1 = 1 CP0 = 1 BS5 = 0 BS4 = 0 BS3 = 0 BS2 = 0 BS1 = 0 1 [1] X means that this bit is not set or reset at power-on reset. [2] The next six bits are written, when bit T/A = 1 in a write sequence. [3] The next six bits are written, when bit T/A = 0 in a write sequence. TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 14 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer 9. Internal circuitry Table 19. Internal pin configuration Symbol Pin Average DC voltage versus band selection TDA6650TT TDA6651TT Low Mid High HBIN1 1 38 n.a. n.a 1.0 V HBIN2 2 37 n.a. n.a 1.0 V Description[1] (38) 1 2 (37) fce899 MBIN 3 36 n.a. 1.8 V n.a. (36) 3 fce901 LBIN 4 35 1.8 V n.a. n.a (35) 4 fce898 RFGND 5 34 - - 5 (34) fce897 IFFIL1 6 33 3.7 V 3.7 V 3.7 V IFFIL2 7 32 3.7 V 3.7 V 3.7 V 7 (32) (33) 6 fce896 BS4 8 31 high-Z or high-Z or high-Z or VCC − VDS VCC − VDS VCC − VDS 8 (31) fce895 TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 15 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Table 19. Internal pin configuration…continued Symbol AGC Pin Average DC voltage versus band selection TDA6650TT TDA6651TT Low Mid High 9 30 0 V or 3.5 V 0 V or 3.5 V 0 V or 3.5 V Description[1] 9 (30) fce907 BS3 10 29 high-Z or high-Z or high-Z or VCC − VDS VCC − VDS VCC − VDS 10 (29) fce893 BS2 11 28 high-Z VCC − VDS high-Z 11 (28) fce892 BS1 12 27 VCC − VDS high-Z high-Z 12 (27) fce891 BVS 13 26 2.5 V 2.5 V 2.5 V (26) 13 mce163 ADC/BS5 14 25 VCEsat or high-Z VCEsat or high-Z VCEsat or high-Z (25) 14 fce887 TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 16 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Table 19. Internal pin configuration…continued Symbol SCL Pin Average DC voltage versus band selection TDA6650TT TDA6651TT Low Mid High 15 24 high-Z high-Z high-Z Description[1] (24) 15 fce889 SDA 16 23 high-Z high-Z high-Z (23) 16 fce888 AS 17 22 1.25 V 1.25 V 1.25 V (22) 17 fce890 XTOUT 18 21 3.45 V 3.45 V 3.45 V 18 (21) mce164 XTAL1 19 20 2.2 V 2.2 V 2.2 V XTAL2 20 19 2.2 V 2.2 V 2.2 V 19 (20) 20 (19) fce883 n.c. 21 18 n.a. TDA6650TT_6651TT_5 Product data sheet not connected © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 17 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Table 19. Internal pin configuration…continued Symbol VT Pin Average DC voltage versus band selection TDA6650TT TDA6651TT Low Mid High 22 17 VVT VVT VVT Description[1] 22 (17) fce884 CP 23 16 1.8 V 1.8 V 1.8 V 23 (16) fce885 VCCD 24 15 5V 5V 5V PLLGND 25 14 - - 25 (14) fce882 VCCA 26 13 5V 5V 5V IFOUTB 27 12 2.1 V 2.1 V 2.1 V IFOUTA 28 11 2.1 V 2.1 V 2.1 V 28 (11) fce886 IFGND 29 10 - - 29 (10) fce880 HOSCIN1 30 9 2.2 V 2.2 V 1.8 V HOSCOUT1 31 8 5V 5V 2.5 V HOSCOUT2 32 7 5V 5V 2.5 V HOSCIN2 33 6 2.2 V 2.2 V 1.8 V (8) 31 32 (7) (6) 33 30 (9) fce879 TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 18 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Table 19. Internal pin configuration…continued Symbol Pin Average DC voltage versus band selection TDA6650TT TDA6651TT Low Mid High MOSCIN1 34 5 2.3 V 1.3 V 2.3 V MOSCIN2 35 4 2.3 V 1.3 V 2.3 V Description[1] 35 (4) 34 (5) fce878 OSCGND 36 3 - - 36 (3) fce908 LOSCOUT 37 2 1.7 V 1.4 V 1.4 V LOSCIN 38 1 2.9 V 3.5 V 3.5 V 37 (2) (1) 38 fce877 [1] The pin numbers in parenthesis refer to the TDA6651TT. 10. Limiting values Table 20. Limiting values In accordance with the Absolute Maximum Rating System (IEC 60134). Positive currents are entering the IC and negative currents are going out of the IC; all voltages are referenced to ground [1]. Symbol Parameter VCCA Conditions Min Max Unit analog supply voltage −0.3 +6 V VCCD digital supply voltage −0.3 +6 V VVT tuning voltage output −0.3 +35 V VSDA serial data input and output voltage −0.3 +6 V ISDA serial data output current 0 10 mA VSCL serial clock input voltage −0.3 +6 V VAS address selection input voltage −0.3 +6 V during acknowledge TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 19 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Table 20. Limiting values…continued In accordance with the Absolute Maximum Rating System (IEC 60134). Positive currents are entering the IC and negative currents are going out of the IC; all voltages are referenced to ground [1]. Symbol Parameter Conditions Min Max Unit Vn voltage on all other inputs, outputs and combined inputs and outputs, except grounds 4.5 V < VCC < 5.5 V −0.3 VCC + 0.3 V IBSn PMOS port output current corresponding port on; open-drain −20 0 mA IBS(tot) sum of all PMOS port output open-drain currents −50 0 mA tsc(max) maximum short-circuit time - 10 s Tstg storage temperature −40 +150 °C −20 Tamb(max) °C - 150 °C Tamb ambient temperature Tj junction temperature each pin to VCC or to ground [2] [1] Maximum ratings cannot be exceeded, not even momentarily without causing irreversible IC damage. Maximum ratings cannot be accumulated. [2] The maximum allowed ambient temperature Tamb(max) depends on the assembly conditions of the package and especially on the design of the printed-circuit board. The application mounting must be done in such a way that the maximum junction temperature is never exceeded. An estimation of the junction temperature can be obtained through measurement of the temperature of the top center of the package (Tpackage). The temperature difference junction to case (∆Tj-c) is estimated at about 13 °C on the demo board (PCB 827-3). The junction temperature: Tj = Tpackage + ∆Tj-c. 11. Thermal characteristics Table 21. Thermal characteristics Symbol Parameter Conditions Rth(j-a) thermal resistance from junction to ambient in free air Typ Unit TDA6650TT 82 K/W TDA6651TT 74 K/W [1] Measured in free air as defined by JEDEC standard JESD51-2. [2] These values are given for information only. The thermal resistance depends strongly on the nature and design of the printed-circuit board used in the application.The thermal resistance given corresponds to the value that can be measured on a multilayer printed-circuit board (4 layers) as defined by JEDEC standard. [3] The junction temperature influences strongly the reliability of an IC. The printed-circuit board used in the application contributes in a large part to the overall thermal characteristic. It must therefore be insured that the junction temperature of the IC never exceeds Tj(max) = 150 °C at the maximum ambient temperature. TDA6650TT_6651TT_5 Product data sheet [1][2][3] © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 20 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer 12. Characteristics Table 22. Characteristics VCCA = VCCD = 5 V; Tamb = 25 °C; values are given for an asymmetrical IF output loaded with a 75 Ω load or with a symmetrical IF output loaded with 1.25 kΩ; positive currents are entering the IC and negative currents are going out of the IC; the performances of the circuits are measured in the measurement circuits Figure 27 and 28 for digital application or in the measurement circuits Figure 29 and 30 for hybrid application; unless otherwise specified. Symbol Parameter Conditions Min Typ Max Unit 4.5 5.0 5.5 V Supply VCC supply voltage ICC supply current PMOS ports off 80 96 115 mA one PMOS port on: sourcing 15 mA 96 112 131 mA two PMOS ports on: one port sourcing 15 mA and one other port sourcing 5 mA 101 117 136 mA power-on reset active if VCC < VPOR - 2.85 3.5 V 64 - 1024 MHz - 4.0 - MHz 350 430 - Ω - 70 - µW General functions VPOR power-on reset supply voltage ∆flock frequency range the PLL is able to synthesize Crystal oscillator[1] fxtal crystal frequency |Zxtal| input impedance (absolute value) fxtal = 4 MHz; VCC = 4.5 V to 5.5 V; Tamb = −20 °C to + Tamb(max), see Section 10 Pxtal crystal drive level fxtal = 4 MHz [2] PMOS ports: pins BS1, BS2, BS3, BS4 and BS5 ILO(off) output leakage current in VCC = 5.5 V; VBS = 0 V off state −10 - - µA VDS(sat) output saturation voltage only corresponding buffer is on, sourcing 15 mA; VDS(sat) = VCC − VBS - 0.2 0.4 V ADC input: pin ADC Vi ADC input voltage see Table 17 0 - 5.5 V IIH HIGH-level input current VADC = VCC - - 10 µA IIL LOW-level input current VADC = 0 V −10 - - µA Address selection input: pin AS IIH HIGH-level input current VAS = 5.5 V - - 10 µA IIL LOW-level input current VAS = 0 V −10 - - µA Bus voltage selection input: pin BVS IIH HIGH-level input current VBVS = 5.5 V - - 100 µA IIL LOW-level input current VBVS = 0 V −100 - - µA - 400 - mV - 175 - Ω Buffered output: pin XTOUT Vo(p-p) square wave AC output voltage (peak-to peak value) Zo output impedance [3] TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 21 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Table 22. Characteristics…continued VCCA = VCCD = 5 V; Tamb = 25 °C; values are given for an asymmetrical IF output loaded with a 75 Ω load or with a symmetrical IF output loaded with 1.25 kΩ; positive currents are entering the IC and negative currents are going out of the IC; the performances of the circuits are measured in the measurement circuits Figure 27 and 28 for digital application or in the measurement circuits Figure 29 and 30 for hybrid application; unless otherwise specified. Symbol Parameter Conditions Min Typ Max Unit I2C-bus Inputs: pins SCL and SDA fclk clock frequency frequency on SCL - - 400 kHz VIL LOW-level input voltage VBVS = 0 V 0 - 0.75 V VBVS = 2.5 V or open-circuit 0 - 1.0 V VBVS = 5 V 0 - 1.5 V VBVS = 0 V 1.75 - 5.5 V VIH IIH IIL HIGH-level input voltage HIGH-level input current LOW-level input current VBVS = 2.5 V or open-circuit 2.3 - 5.5 V VBVS = 5 V 3.0 - 5.5 V VCC = 0 V; VBUS = 5.5 V - - 10 µA VCC = 5.5 V; VBUS = 5.5 V - - 10 µA VCC = 0 V; VBUS = 1.5 V - - 10 µA VCC = 5.5 V; VBUS = 0 V −10 - - µA Output: pin SDA ILH leakage current VSDA = 5.5 V - - 10 µA VO(ack) output voltage during acknowledge ISDA = 3 mA - - 0.4 V see Table 12 - - - µA −15 0 +15 nA Charge pump output: pin CP |Io| output current (absolute value) IL(off) off-state leakage current charge pump off (T[2:0] = 010) Tuning voltage output: pin VT IL(off) leakage current when switched-off tuning supply voltage = 33 V - - 10 µA Vo(cl) output voltage when the loop is closed tuning supply voltage = 33 V; RL = 15 kΩ 0.3 - 32.7 V digital only application: TDA6650TT/C3/S2; TDA6651TT/C3/S2; TDA6651TT/C3/S3 - 0.5 - deg hybrid application: TDA6650TT/C3; TDA6651TT/C3 - 0.6 - deg Noise performance Jφ(rms) phase jitter (RMS value) integrated between 1 kHz and 1 MHz offset from the carrier Low band mixer, including IF amplifier fRF RF frequency picture carrier for digital only application: TDA6650TT/C3/S2; TDA6651TT/C3/S2; TDA6651TT/C3/S3 [4] 47.00 - 160.00 MHz picture carrier for hybrid application: TDA6650TT/C3; TDA6651TT/C3 [4] 43.25 - 157.25 MHz TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 22 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Table 22. Characteristics…continued VCCA = VCCD = 5 V; Tamb = 25 °C; values are given for an asymmetrical IF output loaded with a 75 Ω load or with a symmetrical IF output loaded with 1.25 kΩ; positive currents are entering the IC and negative currents are going out of the IC; the performances of the circuits are measured in the measurement circuits Figure 27 and 28 for digital application or in the measurement circuits Figure 29 and 30 for hybrid application; unless otherwise specified. Symbol Parameter Conditions Gv voltage gain asymmetrical IF output; RL = 75 Ω; see Figure 14 Min Typ Max Unit fRF = 44.25 MHz 21 24 27 dB fRF = 157.25 MHz 21 24 27 dB fRF = 44.25 MHz 25 28 31 dB fRF = 157.25 MHz 25 28 31 dB - 8.0 10.0 dB - 8.0 10.0 dB 107 110 - dBµV 107 110 - dBµV fRF = 44.25 MHz 117 120 - dBµV fRF = 157.25 MHz 117 120 - dBµV - 90 - dBµV symmetrical IF output; RL = 1.25 kΩ; see Figure 15 NF noise figure see Figure 16 and 17 fRF = 50 MHz fRF = 150 MHz Vo output voltage causing 1 % cross modulation in channel asymmetrical application; see Figure 18 [5] fRF = 44.25 MHz fRF = 157.25 MHz symmetrical application; see Figure 19 [5] Vi input voltage causing 750 Hz frequency deviation pulling in channel asymmetrical IF output INTSO2 channel SO2 beat hybrid application: TDA6650TT/C3; TDA6651TT/C3; VRFpix = 80 dBµV [6] 57 60 - dBc Vi(lock) input level without lock-out see Figure 25 [7] - - 120 dBµV Gi input conductance fRF = 44.25 MHz; see Figure 5 - 0.13 - mS fRF = 157.25 MHz; see Figure 5 - 0.11 - mS fRF = 44.25 MHz to 157.25 MHz; see Figure 5 - 1.36 - pF Ci input capacitance Mid band mixer, including IF amplifier fRF RF frequency picture carrier for digital only application: TDA6650TT/C3/S2; TDA6651TT/C3/S2; TDA6651TT/C3/S3 [4] 160.00 - 446.00 MHz picture carrier for hybrid application: TDA6650TT/C3; TDA6651TT/C3 [4] 157.25 - 443.25 MHz TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 23 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Table 22. Characteristics…continued VCCA = VCCD = 5 V; Tamb = 25 °C; values are given for an asymmetrical IF output loaded with a 75 Ω load or with a symmetrical IF output loaded with 1.25 kΩ; positive currents are entering the IC and negative currents are going out of the IC; the performances of the circuits are measured in the measurement circuits Figure 27 and 28 for digital application or in the measurement circuits Figure 29 and 30 for hybrid application; unless otherwise specified. Symbol Parameter Conditions Gv voltage gain asymmetrical IF output; load = 75 Ω; see Figure 14 Min Typ Max Unit fRF = 157.25 MHz 21 24 27 dB fRF = 443.25 MHz 21 24 27 dB fRF = 157.25 MHz 25 28 31 dB fRF = 443.25 MHz 25 28 31 dB - 8.0 10.0 dB - 9.0 11.0 dB 107 110 - dBµV 107 110 - dBµV fRF = 157.25 MHz 117 120 - dBµV fRF = 443.25 MHz 117 120 - dBµV - 80 - dBµV - 89 - dBµV - - 120 dBµV symmetrical IF output; load = 1.25 kΩ; see Figure 15 NF noise figure see Figure 16 and 17 fRF = 150 MHz fRF = 300 MHz Vo output voltage causing 1 % cross modulation in channel asymmetrical application; see Figure 18 [5] fRF = 157.25 MHz fRF = 443.25 MHz symmetrical application; see Figure 19 [5] Vf(N+5)−1 (N + 5) − 1 MHz pulling fRF(wanted) = 443.25 MHz; fosc = 482.15 MHz; fRF(unwanted) = 482.25 MHz Vi input voltage causing 750 Hz frequency deviation pulling in channel asymmetrical IF output Vi(lock) input level without lock-out see Figure 25 Gi input conductance see Figure 6 - 0.3 - mS Ci input capacitance see Figure 6 - 1.1 - pF [8] [7] High band mixer, including IF amplifier fRF Gv RF frequency voltage gain picture carrier for digital only application: TDA6650TT/C3/S2; TDA6651TT/C3/S2; TDA6651TT/C3/S3 [4] 446.00 - 866.00 MHz picture carrier for hybrid application: TDA6650TT/C3; TDA6651TT/C3 [4] 443.25 - 863.25 MHz fRF = 443.25 MHz 31.5 34.5 37.5 dB fRF = 863.25 MHz 31.5 34.5 37.5 dB fRF = 443.25 MHz 35.5 38.5 41.5 dB fRF = 863.25 MHz 35.5 38.5 41.5 dB asymmetrical IF output; load = 75 Ω; see Figure 20 symmetrical IF output; load = 1.25 kΩ; see Figure 21 TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 24 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Table 22. Characteristics…continued VCCA = VCCD = 5 V; Tamb = 25 °C; values are given for an asymmetrical IF output loaded with a 75 Ω load or with a symmetrical IF output loaded with 1.25 kΩ; positive currents are entering the IC and negative currents are going out of the IC; the performances of the circuits are measured in the measurement circuits Figure 27 and 28 for digital application or in the measurement circuits Figure 29 and 30 for hybrid application; unless otherwise specified. Symbol Parameter Conditions NF noise figure, not corrected for image see Figure 22 Min Typ Max Unit - 6.0 8.0 dB - 7.0 9.0 dB 107 110 - dBµV 107 110 - dBµV fRF = 443.25 MHz 117 120 - dBµV fRF = 863.25 MHz 117 120 - dBµV - - 120 dBµV - 80 - dBµV - 79 - dBµV RS - 35 - Ω LS - 8 - nH RS - 36 - Ω LS - 8 - nH fRF = 443.25 MHz fRF = 863.25 MHz Vo output voltage causing 1 % cross modulation in channel asymmetrical application; see Figure 23 [5] fRF = 443.25 MHz fRF = 863.25 MHz symmetrical application; see Figure 24 [5] Vi(lock) input level without lock-out see Figure 26 [7] Vf(N+5)−1 (N + 5) − 1 MHz pulling fRF(wanted) = 815.25 MHz; fosc = 854.15 MHz; fRF(unwanted) = 854.25 MHz [8] Vi input voltage causing 750 Hz frequency deviation pulling in channel asymmetrical IF output Zi input impedance (RS + jLSω) fRF = 443.25 MHz; see Figure 7 fRF = 863.25 MHz; see Figure 7 Low band oscillator fosc [9] oscillator frequency 83.15 - 196.15 MHz [10] - 110 - kHz [11] - 900 - kHz ±1 kHz frequency offset; fcomp = 4 MHz; see Figure 8, 27 and 28 82 95 - dBc/Hz ±10 kHz frequency offset; worst case in the frequency range; see Figure 9, 27 and 28 87 100 - dBc/Hz ±100 kHz frequency offset; worst case in the frequency range; see Figure 10, 27 and 28 104 110 - dBc/Hz ±1.4 MHz frequency offset; worst case in the frequency range; see Figure 27 and 28 - 117 - dBc/Hz ∆fosc(V) oscillator frequency shift with supply voltage ∆fosc(T) oscillator frequency drift with temperature ∆T = 25 °C; VCC = 5 V with compensation Φosc(dig) phase noise, carrier to sideband noise in digital application TDA6650TT/C3/S2; TDA6651TT/C3/S2; TDA6651TT/C3/S3 TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 25 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Table 22. Characteristics…continued VCCA = VCCD = 5 V; Tamb = 25 °C; values are given for an asymmetrical IF output loaded with a 75 Ω load or with a symmetrical IF output loaded with 1.25 kΩ; positive currents are entering the IC and negative currents are going out of the IC; the performances of the circuits are measured in the measurement circuits Figure 27 and 28 for digital application or in the measurement circuits Figure 29 and 30 for hybrid application; unless otherwise specified. Symbol Parameter Conditions Φosc(hyb) phase noise, carrier to sideband noise in hybrid application TDA6650TT/C3; TDA6651TT/C3 RSCp-p ripple susceptibility of VCC (peak-to-peak value) Min Typ Max Unit ±1 kHz frequency offset; fcomp = 4 MHz; see Figure 11, 29, and 30 80 95 - dBc/Hz ±10 kHz frequency offset; worst case in the frequency range; see Figure 12, 29, and 30 85 96 - dBc/Hz ±100 kHz frequency offset; worst case in the frequency range; see Figure 13, 29, and 30 104 110 - dBc/Hz ±1.4 MHz frequency offset; worst case in the frequency range; see Figure 29 and 30 - 117 - dBc/Hz 15 200 - mV VCC = 5 V ± 5 %; worst case in the frequency range; ripple frequency 500 kHz [12] Mid band oscillator [9] fosc oscillator frequency ∆fosc(V) oscillator frequency shift with supply voltage ∆fosc(T) oscillator frequency drift with temperature ∆T = 25 °C; VCC = 5 V with compensation Φosc(dig) phase noise, carrier to sideband noise in digital application TDA6650TT/C3/S2; TDA6651TT/C3/S2; TDA6651TT/C3/S3 Φosc(hyb) phase noise, carrier to sideband noise in hybrid application 196.15 - 482.15 MHz [10] - 110 - kHz [11] - 1500 - kHz ±1 kHz frequency offset; fcomp = 4 MHz; see Figure 8, 27 and 28 85 90 - dBc/Hz ±10 kHz frequency offset; worst case in the frequency range; see Figure 9, 27 and 28 87 95 - dBc/Hz ±100 kHz frequency offset; worst case in the frequency range; see Figure 10, 27 and 28 104 110 - dBc/Hz ±1.4 MHz frequency offset; worst case in the frequency range; see Figure 27 and 28 - 115 - dBc/Hz ±1 kHz frequency offset; fcomp = 4 MHz; see Figure 11, 29, and 30 82 88 - dBc/Hz ±10 kHz frequency offset; worst case in the frequency range; see Figure 12, 29, and 30 85 90 - dBc/Hz ±100 kHz frequency offset; worst case in the frequency range; see Figure 13, 29, and 30 104 110 - dBc/Hz ±1.4 MHz frequency offset; worst case in the frequency range; see Figure 29 and 30 - 115 - dBc/Hz TDA6650TT/C3; TDA6651TT/C3 TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 26 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Table 22. Characteristics…continued VCCA = VCCD = 5 V; Tamb = 25 °C; values are given for an asymmetrical IF output loaded with a 75 Ω load or with a symmetrical IF output loaded with 1.25 kΩ; positive currents are entering the IC and negative currents are going out of the IC; the performances of the circuits are measured in the measurement circuits Figure 27 and 28 for digital application or in the measurement circuits Figure 29 and 30 for hybrid application; unless otherwise specified. Symbol Parameter Conditions RSCp-p ripple susceptibility of VCC (peak-to-peak value) VCC = 5 V ± 5 %; worst case in the frequency range; ripple frequency 500 kHz [12] Min Typ Max Unit 15 140 - mV High band oscillator fosc [9] oscillator frequency 482.15 - 902.15 MHz [10] - 300 - kHz [11] - 1100 - kHz ±1 kHz frequency offset; fcomp = 4 MHz; see Figure 8, 27 and 28 85 89 - dBc/Hz ±10 kHz frequency offset; worst case in the frequency range; see Figure 9, 27 and 28 87 93 - dBc/Hz ±100 kHz frequency offset; worst case in the frequency range; see Figure 10, 27 and 28 104 107 - dBc/Hz ±1.4 MHz frequency offset; worst case in the frequency range; see Figure 27 and 28 - 117 - dBc/Hz ±1 kHz frequency offset; fcomp = 4 MHz; see Figure 11, 29, and 30 80 85 - dBc/Hz ±10 kHz frequency offset; worst case in the frequency range; see Figure 12, 29, and 30 82 86 - dBc/Hz ±100 kHz frequency offset; worst case in the frequency range; see Figure 13, 29, and 30 104 107 - dBc/Hz ±1.4 MHz frequency offset; worst case in the frequency range; see Figure 29 and 30 - 117 - dBc/Hz 15 40 - mV RS at 38.9 MHz - 50 - Ω LS at 38.9 MHz - 5.4 - nH ∆fosc(V) oscillator frequency shift with supply voltage ∆fosc(T) oscillator frequency drift with temperature ∆T = 25 °C; VCC = 5 V; with compensation Φosc(dig) phase noise, carrier to sideband noise in digital application TDA6650TT/C3/S2; TDA6651TT/C3/S2; TDA6651TT/C3/S3 Φosc(hyb) RSCp-p phase noise, carrier to sideband noise in hybrid application TDA6650TT/C3; TDA6651TT/C3 ripple susceptibility of VCC (peak-to-peak value) VCC = 5 V ± 5 %; worst case in the frequency range; ripple frequency 500 kHz output impedance asymmetrical IF output [12] IF amplifier Zo symmetrical IF output - - RS at 38.9 MHz - 100 - Ω LS at 38.9 MHz - 10.4 - nH Rejection at the IF output (IF amplifier in asymmetrical mode) TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 27 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Table 22. Characteristics…continued VCCA = VCCD = 5 V; Tamb = 25 °C; values are given for an asymmetrical IF output loaded with a 75 Ω load or with a symmetrical IF output loaded with 1.25 kΩ; positive currents are entering the IC and negative currents are going out of the IC; the performances of the circuits are measured in the measurement circuits Figure 27 and 28 for digital application or in the measurement circuits Figure 29 and 30 for hybrid application; unless otherwise specified. Symbol Parameter Conditions Min Typ Max Unit INTdiv divider interferences in IF level worst case [13] - - 20 dBµV INTxtal crystal oscillator interferences rejection VIF = 100 dBµV; worst case in the frequency range [14] - - −50 dBc INTf(step) step frequency rejection measured in digital application for DVB-T; fstep = 166.67 kHz; IF = 36.125 MHz [15] - - −50 dBc TDA6650TT/C3; TDA6651TT/C3; TDA6650TT/C3/S2; TDA6651TT/C3/S2 - - −35 dBc measured in hybrid application for DVB-T; fstep = 166.67 kHz; IF = 36.125 MHz [15] - - −57 dBc measured in hybrid application for PAL; fstep = 62.5 kHz; IF = 38.9 MHz [15] - - −57 dBc measured in hybrid application for FM; fstep = 50 kHz; IF = 38.9 MHz [15] - - −57 dBc [16] - - 45 dBµV 122.5 124 125.5 dBµV TDA6651TT/C3/S3 INTXTH crystal oscillator harmonics in the IF frequency AGC output (IF amplifier in asymmetrical mode): pin AGC[17] AGCTOP(p-p) AGC take-over point (peak-to-peak level) bits AL[2:0] = 000 Isource(fast) source current fast 7.5 9.0 11.6 µA Isource(slow) source current slow 185 220 280 nA Vo output voltage TDA6650TT/C3; TDA6651TT/C3; TDA6650TT/C3/S2; TDA6651TT/C3/S2 3.45 3.55 3.8 V TDA6651TT/C3/S3 3.3 3.55 3.8 V 0 - 0.1 V 3.45 3.55 3.8 V maximum level minimum level Vo(dis) output voltage with AGC disabled bits AL[2:0] = 111 TDA6650TT/C3; TDA6651TT/C3; TDA6650TT/C3/S2; TDA6651TT/C3/S2 TDA6651TT/C3/S3 3.3 3.55 3.8 V - - 0.5 dB AGC bit = 0 or AGC not active 0 - 2.8 V high threshold AGC output voltage AGC bit = 1 or AGC active 3.2 3.55 3.8 V leakage current bits AL[2:0] = 110; 0 V < VAGC < 3.5 V −50 - +50 nA VRF(slip) RF voltage range to switch the AGC from active to not active mode VRML low threshold AGC output voltage VRMH ILO [1] Important recommendation: to obtain the performances mentioned in this specification, the serial resistance of the crystal used with this oscillator must never exceed 120 Ω. The crystal oscillator is guaranteed to operate at any supply voltage between 4.5 V and 5.5 V and at any temperature between −20 °C and Tamb(max), as defined in Section 10. TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 28 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer [2] The drive level is expected with a 50 Ω series resistance of the crystal at series resonance. The drive level will be different with other series resistance values. [3] The VXTOUT level is measured when the pin XTOUT is loaded with 5 kΩ in parallel with 10 pF. [4] The RF frequency range is defined by the oscillator frequency range and the Intermediate Frequency (IF). [5] The 1 % cross modulation performance is measured with AGC detector turned off (AGC bits set to 110). [6] Channel SO2 beat is the interfering product of fRFpix, fIF and fosc of channel SO2; fbeat = 37.35 MHz. The possible mechanisms are: fosc − 2 × fIFpix or 2 × fRFpix − fosc. [7] The IF output signal stays stable within the range of the step frequency for any RF input level up to 120 dBµV. [8] (N + 5) − 1 MHz pulling is the input level of channel N + 5, at frequency 1 MHz lower, causing 100 kHz FM sidebands 30 dB below the wanted carrier. [9] Limits are related to the tank circuits used in Figure 27 and 28 for digital application or Figure 29 and 30 for hybrid application. Frequency bands may be adjusted by the choice of external components. [10] The frequency shift is defined as a change in oscillator frequency when the supply voltage varies from VCC = 5 V to 4.5 V or from VCC = 5 V to 5.25 V. The oscillator is free running during this measurement. [11] The frequency drift is defined as a change in oscillator frequency when the ambient temperature varies from Tamb = 25 °C to 50 °C or from Tamb = 25 °C to 0 °C. The oscillator is free running during this measurement. [12] The supply ripple susceptibility is measured in the measurement circuit according to Figure 27, 28, 29 and 30 using a spectrum analyzer connected to the IF output. An unmodulated RF signal is applied to the test board RF input. A sine wave signal with a frequency of 500 kHz is superimposed onto the supply voltage. The amplitude of this ripple signal is adjusted to bring the 500 kHz sidebands around the IF carrier to a level of −53.5 dB with respect to the carrier. [13] This is the level of divider interferences close to the IF frequency. For example channel S3: fosc = 158.15 MHz, 1⁄4 fosc = 39.5375 MHz. The low and mid band inputs must be left open (i.e. not connected to any load or cable); the high band inputs are connected to an hybrid. [14] Crystal oscillator interference means the 4 MHz sidebands caused by the crystal oscillator. [15] The step frequency rejection is the level of step frequency sidebands (e.g. 166.67 kHz) related to the carrier. [16] This is the level of the 9th and 11th harmonics of the 4 MHz crystal oscillator into the IF output. [17] Pin AGC (pin 9 for TDA6650TT, pin 30 for TDA6651TT) must not be connected to a voltage higher than 3.6 V. 1 2 0.5 0.2 5 10 −j ∞ 10 5 2 1 0.5 0.2 0 40 MHz +j 200 MHz 10 5 0.2 2 0.5 1 mce160 Fig 5. Input admittance (s11) of the low band mixer (40 MHz to 200 MHz); Yo = 20 mS TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 29 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer 1 2 0.5 0.2 5 10 −j ∞ 10 5 2 1 0.5 0.2 0 100 MHz +j 10 500 MHz 5 2 0.2 0.5 mce161 1 Fig 6. Input admittance (s11) of the mid band mixer (100 MHz to 500 MHz); Yo = 20 mS 1 0.5 2 900 MHz 0.2 5 400 MHz 10 +j 0 0.2 0.5 1 2 5 ∞ 10 −j 10 5 0.2 2 0.5 1 mce165 Fig 7. Input impedance (s11) of the high band mixer (400 MHz to 900 MHz); Zo = 100 Ω TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 30 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer fce915 −80 Φosc (dBc/Hz) −85 −90 −95 −100 40 140 240 340 440 540 640 740 840 940 fRF (MHz) For measurement circuit see Figure 27 and 28 Fig 8. 1 kHz phase noise typical performance in digital application fce916 −80 Φosc (dBc/Hz) −85 −90 −95 −100 −105 −110 40 140 240 340 440 540 640 740 940 840 fRF (MHz) For measurement circuit see Figure 27 and 28 Fig 9. 10 kHz phase noise typical performance in digital application TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 31 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer fce917 −100 Φosc (dBc/Hz) −105 −110 −115 −120 40 140 240 340 440 540 640 740 940 840 fRF (MHz) For measurement circuit see Figure 27 and 28 Fig 10. 100 kHz phase noise typical performance in digital application fce918 −80 Φosc (dBc/Hz) −85 −90 −95 −100 −105 40 140 240 340 440 540 640 740 940 840 fRF (MHz) For measurement circuit see Figure 29 and 30 Fig 11. 1 kHz phase noise typical performance in hybrid application TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 32 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer fce919 −80 Φosc (dBc/Hz) −85 −90 −95 −100 −105 40 140 240 340 440 540 640 740 840 940 fRF (MHz) For measurement circuit see Figure 29 and 30 Fig 12. 10 kHz phase noise typical performance in hybrid application fce920 −100 Φosc (dBc/Hz) −105 −110 −115 −120 40 140 240 340 440 540 640 740 940 840 fRF (MHz) For measurement circuit see Figure 29 and 30 Fig 13. 100 kHz phase noise typical performance in hybrid application TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 33 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer signal 50 Ω source e LBIN or MBIN Vmeas 50 Ω V 27 Ω IFOUTA spectrum analyzer DUT Vo Vi V'meas 50 Ω IFOUTB RMS voltmeter VCCA fce747 Zi >> 50 Ω → Vi = 2 × Vmeas = 70 dBµV. Vi = Vmeas + 6 dB = 70 dBµV. Vo = V’meas + 3.75 dB. V G v = 20 log -----oVi DVB-T and PAL. IF = 38.9 MHz. Fig 14. Gain (GV) measurement in low and mid band with asymmetrical IF output signal 50 Ω source e LBIN or MBIN Vmeas V 50 Ω transformer IFOUTA DUT Vi spectrum analyzer C N1 Vo N2 50 Ω V'meas IFOUTB RMS voltmeter fce748 Zi >> 50 Ω → Vi = 2 × Vmeas = 70 dBµV. Vi = Vmeas + 6 dB = 70 dBµV. Vo = V’meas + 15 dB (transformer ratio N1/N2 = 5 and transformer loss). V G v = 20 log -----oVi N1 = 10 turns. N2 = 2 turns. N1/N2 = 5. DVB-T and PAL. IF = 38.9 MHz. Fig 15. Gain (GV) measurement in low and mid band with symmetrical IF output TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 34 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer NOISE SOURCE RIM BNC INPUT CIRCUIT LBIN or MBIN 27 Ω NOISE FIGURE METER IFOUTA DUT IFOUTB VCCA fce750 NF = NFmeas − loss of input circuit (dB). Fig 16. Noise figure (NF) measurement in low and mid band with asymmetrical IF output BNC connector Cs Lp Cc TL to the IC mixer input BNC connector Cc Ls Lp Cp TL to the IC mixer input Cp mce452 a. Schematic 1 b. Schematic 2 For fRF = 50 MHz (Schematic 1) For fRF = 300 MHz (Schematic 2) Loss = 0 dB. Loss = 0.5 dB. Cs = 12 pF in parallel with a 0.8 pF to 8 pF trimmer. Cp = 8.2 pF in parallel with a 0.8 pF to 8 pF trimmer. Cp = 18 pF in parallel with a 0.8 pF to 8 pF trimmer. Cc = 4.7 nF. Cc = 4.7 nF. Ls = 2 turns, ∅ 1.5 mm, wire ∅ = 0.4 mm air coil. Lp = 8 turns, ∅ 5 mm, wire ∅ = 0.4 mm air coil Lp = 2 turns, ∅ 1.5 mm, wire ∅ = 0.4 mm air coil. TL = 50 Ω semi rigid cable, length = 75 mm. TL = 50 Ω semi rigid cable, length = 75 mm. For fRF = 150 MHz (Schematic 1) Loss = 0 dB. Cs = 0.8 pF to 8 pF trimmer. Cp = 0.4 pF to 2.5 pF trimmer. Cc = 4.7 nF. Lp = 4 turns, ∅ 4.5 mm, wire ∅ = 0.4 mm air coil TL = 50 Ω semi rigid cable, length = 75 mm. Fig 17. Input circuit for optimum noise figure in low and mid band TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 35 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer FILTER AM = 30 % 1 kHz 50 Ω A unwanted signal source eu LBIN IFOUTA or MBIN C HYBRID B ew modulation analyzer 38.9 MHz V Vmeas 50 Ω IFOUTB D wanted signal source 27 Ω Vo DUT 50 Ω 10 dB attenuator 50 Ω VCCA RMS voltmeter fce749 Vo = Vmeas + 3.75 dB. Wanted signal source at fRFpix is 80 dBµV. Unwanted output signal at fsnd. The level of unwanted signal is measured by causing 0.3 % AM modulation in the wanted signal. Fig 18. Cross modulation measurement in low and mid band with asymmetrical IF output FILTER AM = 30 % 1 kHz 50 Ω A eu unwanted signal source LBIN or MBIN C HYBRID transformer IFOUTA DUT modulation analyzer C N1 N2 V V'meas 38.9 MHz 50 Ω Vo 50 Ω B ew 6 dB attenuator wanted signal source D IFOUTB RMS voltmeter 50 Ω fce793 V’meas = Vo − (transformer ratio N1/N2 = 5 and loss). Wanted signal source at fRFpix is 80 dBµV. The level of unwanted signal Vo at fsnd is measured by causing 0.3 % AM modulation in the wanted output signal. N1 = 10 turns. N2 = 2 turns. N1/N2 = 5. Fig 19. Cross modulation measurement in low and mid band with symmetrical IF output TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 36 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer signal 50 Ω source A e Vmeas 50 Ω V Vi HBIN1 C DUT HYBRID B IFOUTA HBIN2 D 27 Ω spectrum analyzer Vo V'meas 50 Ω IFOUTB RMS 50 Ω voltmeter VCCA fce751 Loss in hybrid = 1 dB. Vi = Vmeas − loss = 70 dBµV. Vo = V’meas + 3.75 dB. V G v = 20 log -----o- . Vi DVB-T and PAL. IF = 38.9 MHz. Fig 20. Gain (GV) measurement in high band with asymmetrical IF output signal 50 Ω source A e Vmeas V 50 Ω Vi C HBIN1 DUT HYBRID B D HBIN2 transformer IFOUTA spectrum analyzer C N1 Vo N2 50 Ω V'meas IFOUTB RMS 50 Ω voltmeter fce752 Loss in hybrid = 1 dB. Vi = Vmeas − loss = 70 dBµV. Vo = V’meas + 15 dB (transformer ratio N1/N2 = 5 and transformer loss). V G v = 20 log -----o- . Vi DVB-T and PAL. IF = 38.9 MHz. Fig 21. Gain (GV) measurement in high band with symmetrical IF output TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 37 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer NOISE SOURCE 27 Ω A HBIN1 C DUT HYBRID B NOISE FIGURE METER IFOUTA D HBIN2 IFOUTB 50 Ω VCCA fce753 Loss in hybrid = 1 dB. NF = NFmeas − loss. Fig 22. Noise figure (NF) measurement in high band with asymmetrical IF output FILTER AM = 30 % 1 kHz 50 Ω unwanted signal eu source A A C 27 Ω C HYBRID HYBRID B B HBIN1 IFOUTA modulation analyzer DUT Vo 50 Ω ew D wanted signal source 50 Ω 10 dB attenuator D HBIN2 38.9 MHz 50 Ω V Vmeas IFOUTB 50 Ω VCCA RMS voltmeter fce754 Wanted signal source at fRFpix is 70 dBµV. Unwanted output signal at fsnd. The level of unwanted signal is measured by causing 0.3 % AM modulation in the wanted signal. Fig 23. Cross modulation measurement in high band with asymmetrical IF output AM = 30 % 1 kHz 50 Ω eu unwanted signal source 6 dB attenuator transformer A A C C HBIN1 IFOUTA HYBRID HYBRID DUT modulation analyzer C N1 N2 V V'meas Vo 50 Ω ew B wanted signal source D B 50 Ω D FILTER 38.9 MHz 50 Ω HBIN2 IFOUTB 50 Ω RMS voltmeter fce794 V’meas = Vo − (transformer ratio N1/N2 = 5 and loss) The level of unwanted signal is measured by causing 0.3 % AM modulation in the wanted signal. N1 = 10 turns. N2 = 2 turns. N1/N2 = 5. Fig 24. Cross modulation measurement in high band with symmetrical IF output TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 38 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer signal 50 Ω source e LBIN or MBIN Vmeas spectrum analyzer DUT 50 Ω V 27 Ω IFOUTA 50 Ω IFOUTB RMS voltmeter VCCA fce755 Zi >> 50 Ω → Vi = 2 × Vmeas. Vi = Vmeas + 6 dB. Fig 25. Maximum RF input level without lock-out in low and mid band with asymmetrical IF output signal 50 Ω source 27 Ω A e Vmeas V 50 Ω Vi HBIN1 D IFOUTA spectrum analyzer DUT HYBRID B RMS voltmeter C HBIN2 50 Ω 50 Ω IFOUTB VCCA fce756 Loss in hybrid = 1 dB. Vi = Vmeas − loss. Fig 26. Maximum RF input level without lock-out in high band with asymmetrical IF output 12.1 PLL loop stability of measurement circuit The TDA6650TT; TDA6651TT PLL loop stability is guaranteed in the configuration of Figure 27, 28, 29 and 30. In this configuration, the external supply source is 30 V minimum, the pull-up resistor R19 is 15 kΩ and all of the local oscillators are aligned to operate at a maximum tuning voltage of 26 V. If the configuration is changed, there might be an impact on the loop stability. For any other configurations, a stability analysis must be performed. The conventional PLL AC model used for the stability analysis, is valid provided the external source (DC supply source or DC-to-DC converter) is able to deliver a minimum current that is equal to the charge pump current in use. TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 39 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer The delivered current can be simply calculated with the following formula: V DC – V T I delivered = ------------------------ > I CP R pu (1) where: Idelivered is the delivered current. VDC is the supply source voltage or DC-to-DC converter output voltage. VT is the tuning voltage. Rpu is the pull-up resistor between the DC supply source (or the DC-to-DC converter output) and the tuning line (R19 in Figure 27 to 30). ICP is the charge pump current in use. TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 40 of 54 xxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxx x x x xxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxx xx xx xxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxx xxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxx x x xxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxx xxx J1 HIGH1 J3 MID J2 HIGH2 C7 1.8 pF N750 C6 C4 4.7 nF 6 1 12 pF 2 3 C26 12 pF R20 1 kΩ R21 R22 1 kΩ D7 R9 330 Ω R23 R10 330 Ω R11 330 Ω 1 kΩ D8 1 (38) (1) 38 2 (37) (2) 37 3 (36) (3) 36 4 (35) (4) 35 5 (34) (5) 34 6 (33) (6) 33 7 (32) (7) 32 TDA6650TT (8) 31 8 (31) (TDA6651TT) 9 (30) (9) 30 10 (29) (10) 29 11 (28) (11) 28 12 (27) (12) 27 13 (26) (13) 26 14 (25) (14) 25 15 (24) (15) 24 16 (23) (16) 23 17 (22) (17) 22 18 (21) (18) 21 19 (20) (19) 20 C19 Y1 18 pF 4 MHz 5 V bus R24 47 pF N750 ST2 ADC R27 3.3 kΩ VCC R14 LOSCIN LOSCOUT OSCGND MOSCIN2 MOSCIN1 HOSCIN2 HOSCOUT2 HOSCOUT1 HOSCIN1 IFGND IFOUTA IFOUTB VCCA L1 25 nH C11 1 pF R28 3.3 kΩ SCL SDA R3 120 pF N750 5.6 kΩ D2 BB178 R4 5.6 kΩ 120 pF N750 N750 C12 1 pF N750 C13 1 pF PLLGND VCCD D3 BB179 L2 13 nH R01255 C14 1 pF N750 R5 5.6 kΩ C18 N750 VCC CP VT n.c. XTAL2 R6 27 Ω 15 pF N470 R8 C17 2.7 nF 5.6 kΩ VCC VCC C15 4.7 nF C34 C33 R13 6.8 kΩ VCC C23 4.7 nF C21 100 nF C16 4.7 nF 5 V bus 1 kΩ ST1 R2 R7 1 kΩ C20 330 pF 30 V AS C29 4.7 nF 1 kΩ J8 1 2 3 4 5 6 C31 10 µF C32 10 µF C30 10 µF 1 2 3 4 J5 R19 15 kΩ R26 27 Ω 41 of 54 © NXP B.V. 2007. All rights reserved. J6 J7 test 5 V bus The pin numbers in parenthesis represent the TDA6651TT. Fig 27. Measurement circuit for digital application, with asymmetrical IF output and DVB-T compliant loop filter 30 V IF out mce162 TDA6650TT; TDA6651TT 1 kΩ D6 BB182 5 V mixer/oscillator and low noise PLL synthesizer Rev. 05 — 10 January 2007 HBIN1 HBIN2 MBIN LBIN RFGND IFFIL1 IFFIL2 BS4 AGC BS3 BS2 BS1 BVS ADC/BS5 SCL SDA AS XTOUT XTAL1 C28 150 nF D5 C5 1 kΩ AGC D4 1.5 pF N750 R1 12 Ω D1 * 6t C27 TP1 C2 4.7 nF 4 2 L4 TOKO 500 nH C1 4.7 nF C3 4.7 nF L3 140 nH R08304 NXP Semiconductors TDA6650TT_6651TT_5 Product data sheet J4 LOW xxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxx x x x xxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxx xx xx xxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxx xxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxx x x xxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxx xxx J3 MID J1 HIGH1 J2 HIGH2 C7 1.8 pF N750 C6 C4 4.7 nF 6 C1 4.7 nF C2 4.7 nF 1 2 3 C27 C26 12 pF 12 pF R20 1 kΩ R21 R22 1 kΩ D7 R9 330 Ω R23 R10 330 Ω R11 330 Ω 1 kΩ D8 47 pF N750 (1) 38 1 (38) (2) 37 2 (37) (3) 36 3 (36) (4) 35 4 (35) (5) 34 5 (34) (6) 33 6 (33) (7) 32 7 (32) TDA6650TT (8) 31 8 (31) (TDA6651TT) (9) 30 9 (30) (10) 29 10 (29) (11) 28 11 (28) (12) 27 12 (27) (13) 26 13 (26) (14) 25 14 (25) (15) 24 15 (24) (16) 23 16 (23) (17) 22 17 (22) (18) 21 18 (21) (19) 20 19 (20) C19 Y1 18 pF 4 MHz 5 V bus R24 ST2 ADC R27 3.3 kΩ VCC R14 LOSCIN LOSCOUT OSCGND MOSCIN2 MOSCIN1 HOSCIN2 HOSCOUT2 HOSCOUT1 HOSCIN1 IFGND IFOUTA IFOUTB VCCA L1 25 nH R3 120 pF N750 5.6 kΩ D2 BB178 R4 C33 C11 1 pF 5.6 kΩ 120 pF N750 N750 C12 1 pF N750 C13 1 pF PLLGND VCCD VCC D3 BB179 L2 13 nH R01255 5.6 kΩ C18 C14 1 pF R6 27 Ω N750 C21 100 nF VCC C16 4.7 nF R5 N750 CP VT n.c. XTAL2 C15 4.7 nF C34 R13 6.8 kΩ 15 pF N470 R8 C17 2.7 nF 5.6 kΩ C24 4.7 nF C23 4.7 nF R7 1 kΩ C25 C20 330 pF 12 pF 5 V bus 1 kΩ ST1 R2 R28 3.3 kΩ SCL SDA 1 VCC C29 4.7 nF 1 kΩ J8 1 2 3 4 5 6 C31 10 µF C32 10 µF C30 10 µF 3 TOKO 7451 30 V AS 2 1 2 3 4 J5 6 4 R19 15 kΩ 42 of 54 © NXP B.V. 2007. All rights reserved. J7 J6 test 5 V bus The pin numbers in parenthesis represent the TDA6651TT. Fig 28. Measurement circuit for digital application, with symmetrical IF output and DVB-T compliant loop filter 30 V IF out fce875 TDA6650TT; TDA6651TT 1 kΩ D6 BB182 5 V mixer/oscillator and low noise PLL synthesizer Rev. 05 — 10 January 2007 HBIN1 HBIN2 MBIN LBIN RFGND IFFIL1 IFFIL2 BS4 AGC BS3 BS2 BS1 BVS ADC/BS5 SCL SDA AS XTOUT XTAL1 C28 150 nF D5 C5 1 kΩ AGC D4 1.5 pF N750 4 R1 12 Ω D1 2 * 6t L4 TOKO 500 nH TP1 C3 4.7 nF L3 140 nH R08304 NXP Semiconductors TDA6650TT_6651TT_5 Product data sheet J4 LOW xxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxx x x x xxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxx xx xx xxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxx xxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxx x x xxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxx xxx J3 MID J1 HIGH1 J2 HIGH2 C7 1.8 pF N750 C6 C4 4.7 nF 6 1 C2 4.7 nF 2 3 C27 C26 12 pF 12 pF R20 R21 1 kΩ R22 (1) 38 1 (38) (2) 37 2 (37) (3) 36 3 (36) (4) 35 4 (35) (5) 34 5 (34) (6) 33 6 (33) (7) 32 7 (32) TDA6650TT (8) 31 8 (31) (TDA6651TT) (9) 30 9 (30) (10) 29 10 (29) (11) 28 11 (28) (12) 27 12 (27) (13) 26 13 (26) (14) 25 14 (25) (15) 24 15 (24) (16) 23 16 (23) (17) 22 17 (22) (18) 21 18 (21) (19) 20 19 (20) 1 kΩ D7 R9 330 Ω R23 R11 330 Ω R10 330 Ω 1 kΩ D8 C19 Y1 18 pF 4 MHz 5 V bus R24 BB182 47 pF N750 ST2 ADC R27 3.3 kΩ VCC R14 LOSCIN LOSCOUT OSCGND MOSCIN2 MOSCIN1 HOSCIN2 HOSCOUT2 HOSCOUT1 HOSCIN1 IFGND IFOUTA IFOUTB VCCA L1 25 nH C11 1 pF R28 3.3 kΩ SCL SDA R3 120 pF N750 5.6 kΩ D2 BB178 R4 5.6 kΩ 120 pF N750 N750 C12 1 pF N750 C13 1 pF PLLGND VCCD D3 BB179 L2 13 nH R01255 C14 1 pF N750 R5 5.6 kΩ C18 N750 VCC CP VT n.c. XTAL2 R6 27 Ω 15 pF N470 R8 C17 4.7 nF 5.6 kΩ VCC VCC C15 4.7 nF C34 C33 R13 1.8 kΩ VCC C23 4.7 nF C21 100 nF C16 4.7 nF 5 V bus 1 kΩ ST1 R2 R7 1 kΩ C20 2.7 nF 30 V AS C29 4.7 nF 1 kΩ J8 1 2 3 4 5 6 C31 10 µF C32 10 µF C30 10 µF 1 2 3 4 J5 R19 15 kΩ R26 27 Ω 43 of 54 © NXP B.V. 2007. All rights reserved. J6 J7 test 30 V 5 V bus The pin numbers in parenthesis represent the TDA6651TT. Fig 29. Measurement circuit for hybrid application, with asymmetrical IF output and loop filter for PAL and DVB-T standards IF out fce909 TDA6650TT; TDA6651TT HBIN1 HBIN2 MBIN LBIN RFGND IFFIL1 IFFIL2 BS4 AGC BS3 BS2 BS1 BVS ADC/BS5 SCL SDA AS XTOUT XTAL1 1 kΩ D6 C5 1 kΩ C28 150 nF D5 12 Ω D1 * 6t AGC D4 1.5 pF N750 R1 5 V mixer/oscillator and low noise PLL synthesizer Rev. 05 — 10 January 2007 TP1 C1 4.7 nF 4 2 L4 TOKO 500 nH C3 4.7 nF L3 140 nH R08304 NXP Semiconductors TDA6650TT_6651TT_5 Product data sheet J4 LOW xxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxx x x x xxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxx xx xx xxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxx xxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxx x x xxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxx xxx J3 MID J1 HIGH1 J2 HIGH2 C7 1.8 pF N750 C6 C4 4.7 nF 6 1 C2 4.7 nF 2 3 C27 C26 12 pF 12 pF R20 R21 1 kΩ R22 1 kΩ D7 R9 330 Ω R23 R10 330 Ω R11 330 Ω 1 kΩ D8 (1) 38 1 (38) (2) 37 2 (37) (3) 36 3 (36) (4) 35 4 (35) (5) 34 5 (34) (6) 33 6 (33) (7) 32 7 (32) TDA6650TT (8) 31 8 (31) (TDA6651TT) (9) 30 9 (30) (10) 29 10 (29) (11) 28 11 (28) (12) 27 12 (27) (13) 26 13 (26) (14) 25 14 (25) (15) 24 15 (24) (16) 23 16 (23) (17) 22 17 (22) (18) 21 18 (21) (19) 20 19 (20) C19 Y1 18 pF 4 MHz 5 V bus R24 BB182 47 pF N750 R2 ST2 ADC LOSCIN LOSCOUT OSCGND MOSCIN2 MOSCIN1 HOSCIN2 HOSCOUT2 HOSCOUT1 HOSCIN1 IFGND IFOUTA IFOUTB VCCA L1 25 nH R3 120 pF N750 5.6 kΩ D2 BB178 R4 C33 C11 1 pF 5.6 kΩ 120 pF N750 N750 C12 1 pF N750 C13 1 pF PLLGND VCCD D3 BB179 L2 13 nH R01255 VCC 5.6 kΩ C18 C14 1 pF R6 27 Ω N750 C21 100 nF VCC C16 4.7 nF R5 N750 CP VT n.c. XTAL2 C15 4.7 nF C34 R13 1.8 kΩ 15 pF N470 R8 C17 4.7 nF 5.6 kΩ C24 4.7 nF C23 4.7 nF R7 1 kΩ C25 C20 2.7 nF 12 pF 5 V bus 1 kΩ R27 3.3 kΩ VCC R14 ST1 R28 3.3 kΩ SCL SDA 1 VCC C29 4.7 nF 1 kΩ J8 1 2 3 4 5 6 6 C31 10 µF C32 10 µF C30 10 µF 3 TOKO 7451 30 V AS 2 1 2 3 4 J5 4 R19 15 kΩ 44 of 54 © NXP B.V. 2007. All rights reserved. J7 J6 test 30 V 5 V bus The pin numbers in parenthesis represent the TDA6651TT. Fig 30. Measurement circuit for hybrid application, with symmetrical IF output and loop filter for PAL and DVB-T standards IF out fce910 TDA6650TT; TDA6651TT HBIN1 HBIN2 MBIN LBIN RFGND IFFIL1 IFFIL2 BS4 AGC BS3 BS2 BS1 BVS ADC/BS5 SCL SDA AS XTOUT XTAL1 1 kΩ D6 C5 * 6t C28 150 nF D5 D1 1 kΩ AGC D4 1.5 pF N750 R1 12 Ω 5 V mixer/oscillator and low noise PLL synthesizer Rev. 05 — 10 January 2007 TP1 C1 4.7 nF 4 2 L4 TOKO 500 nH C3 4.7 nF L3 140 nH R08304 NXP Semiconductors TDA6650TT_6651TT_5 Product data sheet J4 LOW TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer 13. Application information 13.1 Tuning amplifier The tuning amplifier is capable of driving the varicap voltage without an external transistor. The tuning voltage output must be connected to an external load of 15 kΩ which is connected to the tuning voltage supply rail. The loop filter design depends on the oscillator characteristics and the selected reference frequency as well as the required PLL loop bandwidth. Applications with the TDA6650TT; TDA6651TT have a large loop bandwidth, in the order of a few tens of kHz. The calculation of the loop filter elements has to be done for each application, it depends on the reference frequency and charge pump current. 13.2 Crystal oscillator The TDA6650TT; TDA6651TT needs to be used with a 4 MHz crystal in series with a capacitor with a typical value of 18 pF, connected between pin XTAL1 and pin XTAL2. NXP crystal 4322 143 04093 is recommended. When choosing a crystal, take care to select a crystal able to withstand the drive level of the TDA6650TT; TDA6651TT without suffering from accelerated ageing. For optimum performances, it is highly recommended to connect the 4 MHz crystal without any serial resistance. The crystal oscillator of the TDA6650TT; TDA6651TT should not be driven (forced) from an external signal. Do not use the signal on pin XTAL1 or pin XTAL2, or the signal present on the crystal, to drive an external IC or for any other use as this may dramatically degrade the phase noise performance of the TDA6650TT; TDA6651TT. 13.3 Examples of I2C-bus program sequences Table 23 to 30 show various sequences where: S = START A = acknowledge P = STOP. The following conditions apply: LO frequency is 800 MHz fcomp = 166.666 kHz Divider ratio (programmable) N = 4800 BS3 output port is on and all other ports are off: thus the high band is selected Charge pump current ICP = 280 µA Normal mode, with XTOUT buffer on IAGC = 220 nA AGC take-over point is set to 112 dBµV (p-p) Address selection is adjusted to make address C2 valid. TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 45 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer To fully program the device, either sequence of Table 23 or 24 can be used, while other arrangements of the bytes are also possible. Table 23. Complete sequence 1 Start Address byte Divider byte 1 Divider byte 2 Control byte 1[1] Control byte 2 Control byte 1[2] Stop S C2 12 C0 CA A4 84 P A A A A A [1] Control byte 1 with bit T/A = 1, to program test bits T2, T1 and T0 and reference divider ratio bits R2, R1 and R0. [2] Control byte 1 with bit T/A = 0, to program AGC time constant bit ATC and AGC take-over point bits AL2, AL1 and AL0. Table 24. Complete sequence 2 Start Address byte Control byte 1[1] Control byte 2 Divider byte 1 Divider byte 2 Control byte 1[2] Stop S C2 CA A4 12 C0 84 P A A A A A A [1] Control byte 1 with bit T/A = 1, to program test bits T2, T1 and T0 and reference divider ratio bits R2, R1 and R0. [2] Control byte 1 with bit T/A = 0, to program AGC time constant bit ATC and AGC take-over point bits AL2, AL1 and AL0. Table 25. Sequence to program only the main divider ratio Start Address byte Divider byte 1 Divider byte 2 Stop S C2 12 C0 P Table 26. A A A Sequence to change the charge pump current, the ports and the test mode. If the reference divider ratio is changed, it is necessary to send the DB1 and DB2 bytes Start Address byte Control byte 1[1] Control byte 2 Stop S C2 CA A4 P [1] A A Sequence to change the test mode. If the reference divider ratio is changed, it is necessary to send the DB1 and DB2 bytes Start Address byte S C2 [1] A Control byte 1 with bit T/A = 1, to program test bits T2, T1 and T0 and reference divider ratio bits R2, R1 and R0. Table 27. A Control byte 1[1] Stop CA P A Control byte 1 with bit T/A = 1, to program test bits T2, T1 and T0 and reference divider ratio bits R2, R1 and R0. Table 28. Sequence to change the charge pump current, the ports and the AGC data Start Address byte Control byte 1[1] Control byte 2 Stop S C2 82 A4 P [1] A A A Control byte 1 with bit T/A = 0, to program AGC time constant bit ATC and AGC take-over point bits AL2, AL1 and AL0. TDA6650TT_6651TT_5 Product data sheet A © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 46 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer Table 29. Sequence to change only the AGC data Start Address byte S C2 [1] A Stop 84 P A Control byte 1 with bit T/A = 0, to program AGC time constant bit ATC and AGC take-over point bits AL2, AL1 and AL0. Table 30. Sequence to program the main divider, the ALBC on and the test modes in normal mode with XTOUT buffer off Start Address byte Divider byte 1 Divider byte 2 Control byte 1[1] Control byte 2 Control byte 1 Stop S 12 C0 DA 00 C2 P [1] C2 A A A A A A Control byte 1 with bit T/A = 1, to program test bits T2, T1 and T0 and reference divider ratio bits R2, R1 and R0. TDA6650TT_6651TT_5 Product data sheet Control byte 1[1] © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 47 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer 14. Package outline TSSOP38: plastic thin shrink small outline package; 38 leads; body width 4.4 mm; lead pitch 0.5 mm SOT510-1 E D A X c HE y v M A Z 20 38 A2 (A 3) A A1 pin 1 index θ Lp L 1 19 bp e detail X w M 2.5 0 5 mm scale DIMENSIONS (mm are the original dimensions). UNIT A max. A1 A2 A3 bp c D (1) E (2) e HE L Lp v w y Z (1) θ mm 1.1 0.15 0.05 0.95 0.85 0.25 0.27 0.17 0.20 0.09 9.8 9.6 4.5 4.3 0.5 6.4 1 0.7 0.5 0.2 0.08 0.08 0.49 0.21 8 o 0 o Notes 1. Plastic or metal protrusions of 0.15 mm maximum per side are not included. 2. Plastic interlead protrusions of 0.25 mm maximum per side are not included. OUTLINE VERSION SOT510-1 REFERENCES IEC JEDEC JEITA EUROPEAN PROJECTION ISSUE DATE 03-02-18 05-11-02 MO-153 Fig 31. Package outline SOT510-1 (TSSOP38) TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 48 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer 15. Handling information Inputs and outputs are protected against electrostatic discharge in normal handling. However, to be completely safe you must take normal precautions appropriate to handling integrated circuits. 16. Soldering This text provides a very brief insight into a complex technology. A more in-depth account of soldering ICs can be found in Application Note AN10365 “Surface mount reflow soldering description”. 16.1 Introduction to soldering Soldering is one of the most common methods through which packages are attached to Printed Circuit Boards (PCBs), to form electrical circuits. The soldered joint provides both the mechanical and the electrical connection. There is no single soldering method that is ideal for all IC packages. Wave soldering is often preferred when through-hole and Surface Mount Devices (SMDs) are mixed on one printed wiring board; however, it is not suitable for fine pitch SMDs. Reflow soldering is ideal for the small pitches and high densities that come with increased miniaturization. 16.2 Wave and reflow soldering Wave soldering is a joining technology in which the joints are made by solder coming from a standing wave of liquid solder. The wave soldering process is suitable for the following: • Through-hole components • Leaded or leadless SMDs, which are glued to the surface of the printed circuit board Not all SMDs can be wave soldered. Packages with solder balls, and some leadless packages which have solder lands underneath the body, cannot be wave soldered. Also, leaded SMDs with leads having a pitch smaller than ~0.6 mm cannot be wave soldered, due to an increased probability of bridging. The reflow soldering process involves applying solder paste to a board, followed by component placement and exposure to a temperature profile. Leaded packages, packages with solder balls, and leadless packages are all reflow solderable. Key characteristics in both wave and reflow soldering are: • • • • • • Board specifications, including the board finish, solder masks and vias Package footprints, including solder thieves and orientation The moisture sensitivity level of the packages Package placement Inspection and repair Lead-free soldering versus PbSn soldering 16.3 Wave soldering Key characteristics in wave soldering are: TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 49 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer • Process issues, such as application of adhesive and flux, clinching of leads, board transport, the solder wave parameters, and the time during which components are exposed to the wave • Solder bath specifications, including temperature and impurities 16.4 Reflow soldering Key characteristics in reflow soldering are: • Lead-free versus SnPb soldering; note that a lead-free reflow process usually leads to higher minimum peak temperatures (see Figure 32) than a PbSn process, thus reducing the process window • Solder paste printing issues including smearing, release, and adjusting the process window for a mix of large and small components on one board • Reflow temperature profile; this profile includes preheat, reflow (in which the board is heated to the peak temperature) and cooling down. It is imperative that the peak temperature is high enough for the solder to make reliable solder joints (a solder paste characteristic). In addition, the peak temperature must be low enough that the packages and/or boards are not damaged. The peak temperature of the package depends on package thickness and volume and is classified in accordance with Table 31 and 32 Table 31. SnPb eutectic process (from J-STD-020C) Package thickness (mm) Package reflow temperature (°C) Volume (mm3) < 350 ≥ 350 < 2.5 235 220 ≥ 2.5 220 220 Table 32. Lead-free process (from J-STD-020C) Package thickness (mm) Package reflow temperature (°C) Volume (mm3) < 350 350 to 2000 > 2000 < 1.6 260 260 260 1.6 to 2.5 260 250 245 > 2.5 250 245 245 Moisture sensitivity precautions, as indicated on the packing, must be respected at all times. Studies have shown that small packages reach higher temperatures during reflow soldering, see Figure 32. TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 50 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer maximum peak temperature = MSL limit, damage level temperature minimum peak temperature = minimum soldering temperature peak temperature time 001aac844 MSL: Moisture Sensitivity Level Fig 32. Temperature profiles for large and small components For further information on temperature profiles, refer to Application Note AN10365 “Surface mount reflow soldering description”. 17. Abbreviations Table 33. Abbreviations Acronym Description ADC Analog to Digital Converter AGC Automatic Gain Control ALBC Automatic Loop Bandwidth Control DVB-T Digital Video Broadcasting TV I2C-bus Inter-Integrated Circuit bus IF Intermediate Frequency LO Local Oscillator LSB Least Significant Bit MOPLL Mixer Oscillator Phase-Locked Loop MSB Most Significant Bit OFDM Orthogonal Frequency Division Multiplexing PAL Phase Alternation Line PLL Phase-Locked Loop PMOS Positive Channel Metal Oxide Semiconductor QAM Quadrature Amplitude Modulation VCO Voltage Controlled Oscillator VCR Video Cassette Recorder TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 51 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer 18. Revision history Table 34. Revision history Document ID Release date Data sheet status Change notice Supersedes TDA6650TT_6651TT_5 20070110 Product data sheet - TDA6650TT_6651TT_4 Modifications: TDA6650TT_6651TT_4 (9397 750 14178) Modifications: • The format of this data sheet has been redesigned to comply with the new identity guidelines of NXP Semiconductors • • Legal texts have been adapted to the new company name where appropriate Table 3 “Ordering information” updated with type numbers TDA6650TT/C3/S2, DA6651TT/C3/S2 and TDA6651TT/C3/S3 • Table 22 “Characteristics” condition of leakage current (ILO) changed from 0 < VAGC < VCC into 0 V < VAGC < 3.5 V • Table 22 “Characteristics” added value of the TDA6651TT/C3/S3 for INTf(step) (rejection at the IF output) • • Table 22 “Characteristics” added value of the TDA6651TT/C3/S3 for Vo (pin AGC) Table 22 “Characteristics” added value of the TDA6651TT/C3/S3 for Vo(dis) (pin AGC) 20041208 • • • • • • • Product data sheet - TDA6650TT_6651TT_3 Section 3: Note added to the applications list Table 10 on page 11: Notes 1 and 2 added Section 10: Table notes modified Figure 18, 19, 23 and 24: Replaced “1 % AM modulation” with “0.3 % AM modulation” Figure 20: Modified by adding V’meas Figure 24: Added figure note Figure : Changed value of C17 and R13 TDA6650TT_6651TT_3 (9397 750 13025) 20040322 Product specification - TDA6650TT_6651TT_2 TDA6650TT_6651TT_2 (9397 750 11854) 20030911 Preliminary specification - TDA6650TT_6651TT_1 TDA6650TT_6651TT_1 20030717 - - - TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 52 of 54 TDA6650TT; TDA6651TT NXP Semiconductors 5 V mixer/oscillator and low noise PLL synthesizer 19. Legal information 19.1 Data sheet status Document status[1][2] Product status[3] Definition Objective [short] data sheet Development This document contains data from the objective specification for product development. Preliminary [short] data sheet Qualification This document contains data from the preliminary specification. Product [short] data sheet Production This document contains the product specification. [1] Please consult the most recently issued document before initiating or completing a design. [2] The term ‘short data sheet’ is explained in section “Definitions”. [3] The product status of device(s) described in this document may have changed since this document was published and may differ in case of multiple devices. The latest product status information is available on the Internet at URL http://www.nxp.com. 19.2 Definitions Draft — The document is a draft version only. The content is still under internal review and subject to formal approval, which may result in modifications or additions. NXP Semiconductors does not give any representations or warranties as to the accuracy or completeness of information included herein and shall have no liability for the consequences of use of such information. Short data sheet — A short data sheet is an extract from a full data sheet with the same product type number(s) and title. A short data sheet is intended for quick reference only and should not be relied upon to contain detailed and full information. For detailed and full information see the relevant full data sheet, which is available on request via the local NXP Semiconductors sales office. In case of any inconsistency or conflict with the short data sheet, the full data sheet shall prevail. 19.3 Disclaimers General — Information in this document is believed to be accurate and reliable. However, NXP Semiconductors does not give any representations or warranties, expressed or implied, as to the accuracy or completeness of such information and shall have no liability for the consequences of use of such information. Right to make changes — NXP Semiconductors reserves the right to make changes to information published in this document, including without limitation specifications and product descriptions, at any time and without notice. This document supersedes and replaces all information supplied prior to the publication hereof. Suitability for use — NXP Semiconductors products are not designed, authorized or warranted to be suitable for use in medical, military, aircraft, space or life support equipment, nor in applications where failure or malfunction of a NXP Semiconductors product can reasonably be expected to result in personal injury, death or severe property or environmental damage. NXP Semiconductors accepts no liability for inclusion and/or use of NXP Semiconductors products in such equipment or applications and therefore such inclusion and/or use is at the customer’s own risk. Applications — Applications that are described herein for any of these products are for illustrative purposes only. NXP Semiconductors makes no representation or warranty that such applications will be suitable for the specified use without further testing or modification. Limiting values — Stress above one or more limiting values (as defined in the Absolute Maximum Ratings System of IEC 60134) may cause permanent damage to the device. Limiting values are stress ratings only and operation of the device at these or any other conditions above those given in the Characteristics sections of this document is not implied. Exposure to limiting values for extended periods may affect device reliability. Terms and conditions of sale — NXP Semiconductors products are sold subject to the general terms and conditions of commercial sale, as published at http://www.nxp.com/profile/terms, including those pertaining to warranty, intellectual property rights infringement and limitation of liability, unless explicitly otherwise agreed to in writing by NXP Semiconductors. In case of any inconsistency or conflict between information in this document and such terms and conditions, the latter will prevail. No offer to sell or license — Nothing in this document may be interpreted or construed as an offer to sell products that is open for acceptance or the grant, conveyance or implication of any license under any copyrights, patents or other industrial or intellectual property rights. 19.4 Trademarks Notice: All referenced brands, product names, service names and trademarks are the property of their respective owners. I2C-bus — logo is a trademark of NXP B.V. 20. Contact information For additional information, please visit: http://www.nxp.com For sales office addresses, send an email to: [email protected] TDA6650TT_6651TT_5 Product data sheet © NXP B.V. 2007. All rights reserved. Rev. 05 — 10 January 2007 53 of 54 NXP Semiconductors TDA6650TT; TDA6651TT 5 V mixer/oscillator and low noise PLL synthesizer 21. Contents 1 2 3 3.1 4 5 6 6.1 6.2 7 7.1 7.2 7.3 8 8.1 8.1.1 8.1.2 8.1.3 8.1.4 8.1.5 8.1.6 8.2 8.3 9 10 11 12 12.1 13 13.1 13.2 13.3 14 15 16 16.1 16.2 16.3 16.4 17 18 19 19.1 19.2 General description . . . . . . . . . . . . . . . . . . . . . . 1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 Application summary . . . . . . . . . . . . . . . . . . . . 3 Ordering information . . . . . . . . . . . . . . . . . . . . . 3 Block diagram . . . . . . . . . . . . . . . . . . . . . . . . . . 4 Pinning information . . . . . . . . . . . . . . . . . . . . . . 5 Pin description . . . . . . . . . . . . . . . . . . . . . . . . . 5 Pinning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 Functional description . . . . . . . . . . . . . . . . . . . 6 Mixer, Oscillator and PLL (MOPLL) functions. . 6 I2C-bus voltage . . . . . . . . . . . . . . . . . . . . . . . . . 7 Phase noise, I2C-bus traffic and crosstalk . . . . 7 2 I C-bus protocol . . . . . . . . . . . . . . . . . . . . . . . . . 8 Write mode; R/W = 0 . . . . . . . . . . . . . . . . . . . . 8 I2C-bus address selection. . . . . . . . . . . . . . . . 10 XTOUT output buffer and mode setting . . . . . 10 Step frequency setting . . . . . . . . . . . . . . . . . . 10 AGC detector setting . . . . . . . . . . . . . . . . . . . 11 Charge pump current setting . . . . . . . . . . . . . 11 Automatic Loop Bandwidth Control (ALBC) . . 12 Read mode; R/W = 1 . . . . . . . . . . . . . . . . . . . 13 Status at power-on reset. . . . . . . . . . . . . . . . . 14 Internal circuitry. . . . . . . . . . . . . . . . . . . . . . . . 15 Limiting values. . . . . . . . . . . . . . . . . . . . . . . . . 19 Thermal characteristics. . . . . . . . . . . . . . . . . . 20 Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . 21 PLL loop stability of measurement circuit . . . . 39 Application information. . . . . . . . . . . . . . . . . . 45 Tuning amplifier. . . . . . . . . . . . . . . . . . . . . . . . 45 Crystal oscillator . . . . . . . . . . . . . . . . . . . . . . . 45 Examples of I2C-bus program sequences . . . 45 Package outline . . . . . . . . . . . . . . . . . . . . . . . . 48 Handling information. . . . . . . . . . . . . . . . . . . . 49 Soldering . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49 Introduction to soldering . . . . . . . . . . . . . . . . . 49 Wave and reflow soldering . . . . . . . . . . . . . . . 49 Wave soldering . . . . . . . . . . . . . . . . . . . . . . . . 49 Reflow soldering . . . . . . . . . . . . . . . . . . . . . . . 50 Abbreviations . . . . . . . . . . . . . . . . . . . . . . . . . . 51 Revision history . . . . . . . . . . . . . . . . . . . . . . . . 52 Legal information. . . . . . . . . . . . . . . . . . . . . . . 53 Data sheet status . . . . . . . . . . . . . . . . . . . . . . 53 Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53 19.3 19.4 20 21 Disclaimers. . . . . . . . . . . . . . . . . . . . . . . . . . . Trademarks . . . . . . . . . . . . . . . . . . . . . . . . . . Contact information . . . . . . . . . . . . . . . . . . . . Contents. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53 53 53 54 Please be aware that important notices concerning this document and the product(s) described herein, have been included in section ‘Legal information’. © NXP B.V. 2007. All rights reserved. For more information, please visit: http://www.nxp.com For sales office addresses, please send an email to: [email protected] Date of release: 10 January 2007 Document identifier: TDA6650TT_6651TT_5