RF COMMUNICATIONS PRODUCTS SA604A High performance low power FM IF system Product specification Replaces data of December 15, 1994 IC17 Data Handbook Philips Semiconductors 1997 Nov 07 Philips Semiconductors Product specification High performance low power FM IF system DESCRIPTION SA604A PIN CONFIGURATION The SA604A is an improved monolithic low-power FM IF system incorporating two limiting intermediate frequency amplifiers, quadrature detector, muting, logarithmic received signal strength indicator, and voltage regulator. The SA604A features higher IF bandwidth (25MHz) and temperature compensated RSSI and limiters permitting higher performance application compared with the SA604. The SA604A is available in a 16-lead SO (surface-mounted miniature) package. D Package IF AMP DECOUPLING 1 16 IF AMP INPUT GND 2 15 IF AMP DECOUPLING 14 IF AMP OUTPUT MUTE INPUT 3 VCC 4 13 GND RSSI OUTPUT 5 FEATURES • Low power consumption: 3.3mA typical • Temperature compensated logarithmic Received Signal Strength 12 LIMITER INPUT MUTE AUDIO OUTPUT 6 11 LIMITER DECOUPLING UNMUTE AUDIO OUTPUT 7 10 LIMITER DECOUPLING QUADRATURE INPUT 8 9 LIMITER Indicator (RSSI) with a dynamic range in excess of 90dB SR00311 • Two audio outputs - muted and unmuted • Low external component count; suitable for crystal/ceramic filters • Excellent sensitivity: 1.5µV across input pins (0.22µV into 50Ω Figure 1. Pin Configuration APPLICATIONS • Cellular radio FM IF • High performance communications receivers • Intermediate frequency amplification and detection up to 25MHz • RF level meter • Spectrum analyzer • Instrumentation • FSK and ASK data receivers matching network) for 12dB SINAD (Signal to Noise and Distortion ratio) at 455kHz • SA604A meets cellular radio specifications ORDERING INFORMATION DESCRIPTION 16-Pin Plastic Small Outline (SO) package (Surface-mount) TEMPERATURE RANGE ORDER CODE DWG # -40 to +85°C SA604AD SOT109-1 ABSOLUTE MAXIMUM RATINGS SYMBOL PARAMETER VCC Single supply voltage TSTG Storage temperature range TA Operating ambient temperature range SA604A θJA Thermal impedance 1997 Nov 07 RATING D package 2 UNITS 9 V -65 to +150 °C 40 to +85 °C 90 °C/W 853-1431 18663 Philips Semiconductors Product specification High performance low power FM IF system SA604A BLOCK DIAGRAM 16 15 14 13 12 11 10 9 GND IF AMP LIMITER LIMITER QUAD DET SIGNAL STRENGTH VOLTAGE REGULATOR MUTE VCC GND 1 2 3 4 5 6 7 8 SR00312 Figure 2. Block Diagram DC ELECTRICAL CHARACTERISTICS VCC = +6V, TA = 25°C; unless otherwise stated. LIMITS SYMBOL PARAMETER TEST CONDITIONS SA604A MIN VCC Power supply voltage range 4.5 ICC DC current drain 2.5 Mute switch input threshold 1997 Nov 07 (ON) (OFF) 1.7 3 TYP 3.3 UNITS MAX 8.0 V 4.0 mA 1.0 V V Philips Semiconductors Product specification High performance low power FM IF system SA604A AC ELECTRICAL CHARACTERISTICS Typical reading at TA = 25°C; VCC = ±6V, unless otherwise stated. IF frequency = 455kHz; IF level = -47dBm; FM modulation = 1kHz with ±8kHz peak deviation. Audio output with C-message weighted filter and de-emphasis capacitor. Test circuit Figure 3. The parameters listed below are tested using automatic test equipment to assure consistent electrical characterristics. The limits do not represent the ultimate performance limits of the device. Use of an optimized RF layout will improve many of the listed parameters. LIMITS SYMBOL PARAMETER TEST CONDITIONS SA604A MIN Input limiting -3dB Test at Pin 16 AM rejection 80% AM 1kHz Recovered audio level 15nF de-emphasis Recovered audio level 150pF de-emphasis THD Total harmonic distortion S/N Signal-to-noise ratio RSSI output1 TYP UNITS MAX -92 dBm/50Ω 30 34 dB 80 175 -34 No modulation for noise 260 mVRMS 530 mVRMS -42 dB 73 dB RF level = -118dBm 0 160 650 mV RF level = -68dBm 1.9 2.65 3.1 V RF level = -18dBm 4.0 4.85 5.6 V RSSI range R4 = 100k (Pin 5) 90 dB RSSI accuracy R4 = 100k (Pin 5) ±1.5 dB IF input impedance 1.4 1.6 kΩ IF output impedance 0.85 1.0 kΩ Limiter input impedance 1.4 1.6 kΩ Unmuted audio output resistance 58 kΩ Muted audio output resistance 58 kΩ NOTE: 1. SA604 data sheets refer to power at 50Ω input termination; about 21dB less power actually enters the internal 1.5k input. SA604 (50) SA604A (1.5k)/SA605 (1.5k -97dBm -118dBm -47dBm -68dBm +3dBm -18dBm The SA605 and SA604A are both derived from the same basic die. The SA605 performance plots are directly applicable to the SA604A. 1997 Nov 07 4 Philips Semiconductors Product specification High performance low power FM IF system SA604A F1 NE604A TEST CIRCUIT C4 Q = 20 LOADED C1 R2 C2 C5 R3 C6 INPUT F2 R1 16 15 14 13 12 11 10 9 C7 SA604A C3 1 2 3 4 5 6 C8 S1 MUTE INPUT C10 AUDIO OUTPUT C11 RSSI OUTPUT VCC 6.8µF +20% 25V Tantalum 455kHz Ceramic Filter Murata SFG455A3 455kHz (Ce = 180pF) TOKO RMC 2A6597H 51Ω +1% 1/4W Metal Film M U T E AUDIO DATA 100kΩ +1% 1/4W Metal Film GND 1500Ω +5% 1/8W Carbon Composition R4 GND 1500Ω +1% 1/4W Metal Film R3 RSSI VCC R2 IF SIGNETICS NE604A TEST CKT GND OFF C12 F1 F2 R1 ON 100nF +10% 50V 10pF +2% 100V NPO Ceramic 100nF +10% 50V 100nF +10% 50V 15nF +10% 50V 150pF +2% 100V N1500 Ceramic 1nF +10% 100V K2000-Y5P Ceramic SIGNETICS NE604A TEST CKT INPUT 100nF + 80 – 20% 63V K10000–25V Ceramic 100nF +10% 50V 100nF +10% 50V 100nF +10% 50V C5 C6 C7 C8 C9 C10 C11 DATA OUTPUT IF C1 C2 C3 C4 8 C9 R4 C12 7 INPUT M U T E GND OFF ON RSSI VCC AUDIO GND DATA GND SR00313 Figure 3. SA604A Test Circuit 1997 Nov 07 5 Philips Semiconductors Product specification High performance low power FM IF system 16 15 14 13 SA604A 12 11 10 9 GND 42k 42k 700 7k 1.6k 1.6k 40k 40k 700 35k 2k FULL WAVE RECT. FULL WAVE RECT. 4.5k 2k 8k VOLTAGE/ CURRENT CONVERTER VEE MUTE VOLT REG VOLT REG QUAD VCC DET BAND GAP VOLT VCC 80k 80k VCC GND 2 55k 55k 80k 1 40k 40k 3 4 5 6 7 8 SR00314 Figure 4. Equivalent Circuit 1997 Nov 07 6 Philips Semiconductors Product specification High performance low power FM IF system 0.5 to 1.3µH SA604A SFG455A3 22pF 1nF 5.5µH 0.1µF NE604A TEST CIRCUIT 0.1µF 455kHz Q=20 44.545 3rd OVERTURE XTAL SFG455A3 5.6pF 0.1µF 10pF +6V 6.8µF 8 100nF 7 6 16 5 15 14 13 12 11 10 9 10nF 0.1µF SA602 1 2 SA604A 0.1µF 3 4 1 2 47pF 3 4 5 6 0.1µF 0.21 to 0.28µH 100k 7 8 DATA OUT +6V C–MSG FILTER 22pF AUDIO OUT MUTE 100nF RSSI AUDIO OUT – ‘C’ MESSAGE WEIGHTED (0dB REF = RECOVERED AUDIO FOR +8kHz PEAK DEVIATION (dB) – 10 NE604A IF INPUT (µV) (1500Ω) 100 1k 10k 100k AUDIO –0 4V RSSI (VOLTS) –20 3V THD + NOISE –40 2V –60 AM (80% MOD) 1V NOISE –80 –120 –100 –80 –60 –40 NE602 RF INPUT (dBm) (50Ω) –20 SR00315 Figure 5. Typical Application Cellular Radio (45MHz to 455kHz) output of the first limiter is a low impedance emitter follower with 1kΩ of equivalent series resistance. The second limiting stage consists of three differential amplifiers with a gain of 62dB and a small signal AC bandwidth of 28MHz. The outputs of the final differential stage are buffered to the internal quadrature detector. One of the outputs is available at Pin 9 to drive an external quadrature capacitor and L/C quadrature tank. CIRCUIT DESCRIPTION The SA604A is a very high gain, high frequency device. Correct operation is not possible if good RF layout and gain stage practices are not used. The SA604A cannot be evaluated independent of circuit, components, and board layout. A physical layout which correlates to the electrical limits is shown in Figure 3. This configuration can be used as the basis for production layout. Both of the limiting amplifier stages are DC biased using feedback. The buffered output of the final differential amplifier is fed back to the input through 42kΩ resistors. As shown in Figure 4, the input impedance is established for each stage by tapping one of the feedback resistors 1.6kΩ from the input. This requires one additional decoupling capacitor from the tap point to ground. The SA604A is an IF signal processing system suitable for IF frequencies as high as 21.4MHz. The device consists of two limiting amplifiers, quadrature detector, direct audio output, muted audio output, and signal strength indicator (with output characteristic). The sub-systems are shown in Figure 4. A typical application with 45MHz input and 455kHz IF is shown in Figure 5. Because of the very high gain, bandwidth and input impedance of the limiters, there is a very real potential for instability at IF frequencies above 455kHz. The basic phenomenon is shown in Figure 8. Distributed feedback (capacitance, inductance and radiated fields) IF Amplifiers The IF amplifier section consists of two log-limiting stages. The first consists of two differential amplifiers with 39dB of gain and a small signal bandwidth of 41MHz (when driven from a 50Ω source). The 1997 Nov 07 7 Philips Semiconductors Product specification High performance low power FM IF system SA604A 42k V+ 15 16 70014 7k 1.6k 1 40k BPF BPF SR00316 Figure 6. First Limiter Bias SR00318 42k 9 11 Figure 8. Feedback Paths V+ 12 40k 8 10 40k 80k SR00317 Figure 7. Second Limiter and Quadrature Detector HIGH IMPEDANCE BPF HIGH IMPEDANCE BPF LOW IMPEDANCE a. Terminating High Impedance Filters with Transformation to Low Impedance BPF BPF A RESISTIVE LOSS INTO BPF b. Low Impedance Termination and Gain Reduction Figure 9. Practical Termination 1997 Nov 07 8 SR00319 Philips Semiconductors Product specification High performance low power FM IF system SA604A 430 16 15 14 13 12 11 10 9 6 7 8 SA604A 430 1 2 3 4 5 SR00320 Figure 10. Crystal Input Filter with Ceramic Interstage Filter As illustrated in Figure 10, 430Ω external resistors are applied in parallel to the internal 1.6kΩ load resistors, thus presenting approximately 330Ω to the filters. The input filter is a crystal type for narrowband selectivity. The filter is terminated with a tank which transforms to 330Ω. The interstage filter is a ceramic type which doesn’t contribute to system selectivity, but does suppress wideband noise and stray signal pickup. In wideband 10.7MHz IFs the input filter can also be ceramic, directly connected to Pin 16. forms a divider from the output of the limiters back to the inputs (including RF input). If this feedback divider does not cause attenuation greater than the gain of the forward path, then oscillation or low level regeneration is likely. If regeneration occurs, two symptoms may be present: (1)The RSSI output will be high with no signal input (should nominally be 250mV or lower), and (2) the demodulated output will demonstrate a threshold. Above a certain input level, the limited signal will begin to dominate the regeneration, and the demodulator will begin to operate in a “normal” manner. In some products it may be impractical to utilize shielding, but this mechanism may be appropriate to 10.7MHz and 21.4MHz IF. One of the benefits of low current is lower radiated field strength, but lower does not mean non-existent. A spectrum analyzer with an active probe will clearly show IF energy with the probe held in the proximity of the second limiter output or quadrature coil. No specific recommendations are provided, but mechanical shielding should be considered if layout, bypass, and input impedance reduction do not solve a stubborn instability. There are three primary ways to deal with regeneration: (1) Minimize the feedback by gain stage isolation, (2) lower the stage input impedances, thus increasing the feedback attenuation factor, and (3) reduce the gain. Gain reduction can effectively be accomplished by adding attenuation between stages. This can also lower the input impedance if well planned. Examples of impedance/gain adjustment are shown in Figure 9. Reduced gain will result in reduced limiting sensitivity. The final stability consideration is phase shift. The phase shift of the limiters is very low, but there is phase shift contribution from the quadrature tank and the filters. Most filters demonstrate a large phase shift across their passband (especially at the edges). If the quadrature detector is tuned to the edge of the filter passband, the combined filter and quadrature phase shift can aggravate stability. This is not usually a problem, but should be kept in mind. A feature of the SA604A IF amplifiers, which is not specified, is low phase shift. The SA604A is fabricated with a 10GHz process with very small collector capacitance. It is advantageous in some applications that the phase shift changes only a few degrees over a wide range of signal input amplitudes. Stability Considerations The high gain and bandwidth of the SA604A in combination with its very low currents permit circuit implementation with superior performance. However, stability must be maintained and, to do that, every possible feedback mechanism must be addressed. These mechanisms are: 1) Supply lines and ground, 2) stray layout inductances and capacitances, 3) radiated fields, and 4) phase shift. As the system IF increases, so must the attention to fields and strays. However, ground and supply loops cannot be overlooked, especially at lower frequencies. Even at 455kHz, using the test layout in Figure 3, instability will occur if the supply line is not decoupled with two high quality RF capacitors, a 0.1µF monolithic right at the VCC pin, and a 6.8µF tantalum on the supply line. An electrolytic is not an adequate substitute. At 10.7MHz, a 1µF tantalum has proven acceptable with this layout. Every layout must be evaluated on its own merit, but don’t underestimate the importance of good supply bypass. Quadrature Detector Figure 7 shows an equivalent circuit of the SA604A quadrature detector. It is a multiplier cell similar to a mixer stage. Instead of mixing two different frequencies, it mixes two signals of common frequency but different phase. Internal to the device, a constant amplitude (limited) signal is differentially applied to the lower port of the multiplier. The same signal is applied single-ended to an external capacitor at Pin 9. There is a 90° phase shift across the plates of this capacitor, with the phase shifted signal applied to the upper port of the multiplier at Pin 8. A quadrature tank (parallel L/C network) permits frequency selective phase shifting at the IF frequency. This quadrature tank must be returned to ground through a DC blocking capacitor. The loaded Q of the quadrature tank impacts three fundamental aspects of the detector: Distortion, maximum modulated peak deviation, and audio output amplitude. Typical quadrature curves are illustrated in Figure 12. The phase angle translates to a shift in the multiplier output voltage. At 455kHz, if the layout of Figure 3 or one substantially similar is used, it is possible to directly connect ceramic filters to the input and between limiter stages with no special consideration. At frequencies above 2MHz, some input impedance reduction is usually necessary. Figure 9 demonstrates a practical means. 1997 Nov 07 9 Philips Semiconductors Product specification High performance low power FM IF system Thus a small deviation gives a large output with a high Q tank. However, as the deviation from resonance increases, the non-linearity of the curve increases (distortion), and, with too much deviation, the signal will be outside the quadrature region (limiting the peak deviation which can be demodulated). If the same peak deviation is applied to a lower Q tank, the deviation will remain in a region of the curve which is more linear (less distortion), but creates a smaller phase angle (smaller output amplitude). Thus the Q of the quadrature tank must be tailored to the design. Basic equations and an example for determining Q are shown below. This explanation includes first-order effects only. SA604A ⇒ VOUT = 1 2 A Cos 2 π – 2 2Q1 ω1 ω (5) )ω = 1 A2 Sin 2Q1 2 ω1 ( VOUT ∝ 2Q1 For 2Q1ω ω1 ω = ω1 << 2Q1 ( ω1 + ∆ω ω1 ) (6) π 2 Which is discriminated FM output. (Note that ∆ω is the deviation frequency from the carrier ω1. Frequency Discriminator Design Equations for SA604A Ref. Krauss, Raab, Bastian; Solid State Radio Eng.; Wiley, 1980, p. 311. Example: At 455kHz IF, with +5kHz FM deviation. The maximum normalized frequency will be 455 +5kHz = 1.010 or 0.990 455 VOUT Go to the f vs. normalized frequency curves (Figure 12) and draw a vertical straight line at ω ω1 = 1.01. SR00321 Figure 11. VO = CS CP + C S 1 1+ where ω1 = ω1 ω1 Q1S ( S) + 2 (1a) VIN The curves with Q = 100, Q = 40 are not linear, but Q = 20 and less shows better linearity for this application. Too small Q decreases the amplitude of the discriminated FM signal. (Eq. 6) ⇒ Choose a Q = 20 (1b) The internal R of the 604A is 40k. From Eq. 1c, and then 1b, it results that 1 L(CP + CS) Q1 = R (CP + CS) ω1 CP + CS = 174pF and L = 0.7mH. (1c) A more exact analysis including the source resistance of the previous stage shows that there is a series and a parallel resonance in the phase detector tank. To make the parallel and series resonances close, and to get maximum attenuation of higher harmonics at 455kHz IF, we have found that a CS = 10pF and CP = 164pF (commercial values of 150pF or 180pF may be practical), will give the best results. A variable inductor which can be adjusted around 0.7mH should be chosen and optimized for minimum distortion. (For 10.7MHz, a value of CS = 1pF is recommended.) From the above equation, the phase shift between nodes 1 and 2, or the phase across CS will be: ω1 (2) Q ω 1 φ = ∠VO - ∠VIN = tg-1 ω1 2 1 – (ω) Figure 12 is the plot of φ vs. ( ωω1 ) Audio Outputs It is notable that at ω = ω1, the phase shift is Two audio outputs are provided. Both are PNP current-to-voltage converters with 55kΩ nominal internal loads. The unmuted output is always active to permit the use of signaling tones in systems such as cellular radio. The other output can be muted with 70dB typical attenuation. The two outputs have an internal 180° phase difference. π and the response is close to a straight ∆φ 2Q1 = line with a slope of 2 ω1 ∆ω The signal VO would have a phase shift of π – 2Q1 ω with respect to the V . IN ω1 2 If VIN = A Sin ωt ⇒ VO = A Sin ωt + π 2 – 2Q1 ω1 The nominal frequency response of the audio outputs is 300kHz. this response can be increased with the addition of external resistors from the output pins to ground in parallel with the internal 55k resistors, thus lowering the output time constant. Singe the output structure is a current-to-voltage converter (current is driven into the resistance, creating a voltage drop), adding external parallel resistance also has the effect of lowering the output audio amplitude and DC level. (3) ω Multiplying the two signals in the mixer, and low pass filtering yields: (4) VIN • VO = A2 Sin ωt Sin ωt + π 2 – 2Q1 ω1 This technique of audio bandwidth expansion can be effective in many applications such as SCA receivers and data transceivers. Because the two outputs have a 180° phase relationship, FSK demodulation can be accomplished by applying the two output ω after low pass filtering 1997 Nov 07 10 Philips Semiconductors Product specification High performance low power FM IF system SA604A optimized at 0.22µV for 12dB SINAD with minor change in the RSSI linearity. differentially across the inputs of an op amp or comparator. Once the threshold of the reference frequency (or “no-signal” condition) has been established, the two outputs will shift in opposite directions (higher or lower output voltage) as the input frequency shifts. The output of the comparator will be logic output. The choice of op amp or comparator will depend on the data rate. With high IF frequency (10MHz and above), and wide IF bandwidth (L/C filters) data rates in excess of 4Mbaud are possible. Any application which requires optimized RSSI linearity, such as spectrum analyzers, cellular radio, and certain types of telemetry, will require careful attention to limiter interstage component selection. This will be especially true with high IF frequencies which require insertion loss or impedance reduction for stability. At low frequencies the RSSI makes an excellent logarithmic AC voltmeter. RSSI The “received signal strength indicator”, or RSSI, of the SA604A demonstrates monotonic logarithmic output over a range of 90dB. The signal strength output is derived from the summed stage currents in the limiting amplifiers. It is essentially independent of the IF frequency. Thus, unfiltered signals at the limiter inputs, spurious products, or regenerated signals will manifest themselves as RSSI outputs. An RSSI output of greater than 250mV with no signal (or a very small signal) applied, is an indication of possible regeneration or oscillation. For data applications the RSSI is effective as an amplitude shift keyed (ASK) data slicer. If a comparator is applied to the RSSI and the threshold set slightly above the no signal level, when an in-band signal is received the comparator will be sliced. Unlike FSK demodulation, the maximum data rate is somewhat limited. An internal capacitor limits the RSSI frequency response to about 100kHz. At high data rates the rise and fall times will not be symmetrical. The RSSI output is a current-to-voltage converter similar to the audio outputs. However, an external resistor is required. With a 91kΩ resistor, the output characteristic is 0.5V for a 10dB change in the input amplitude. In order to achieve optimum RSSI linearity, there must be a 12dB insertion loss between the first and second limiting amplifiers. With a typical 455kHz ceramic filter, there is a nominal 4dB insertion loss in the filter. An additional 6dB is lost in the interface between the filter and the input of the second limiter. A small amount of additional loss must be introduced with a typical ceramic filter. In the test circuit used for cellular radio applications (Figure 5) the optimum linearity was achieved with a 5.1kΩ resistor from the output of the first limiter (Pin 14) to the input of the interstage filter. With this resistor from Pin 14 to the filter, sensitivity of 0.25µV for 12dB Additional Circuitry Internal to the SA604A are voltage and current regulators which have been temperature compensated to maintain the performance of the device over a wide temperature range. These regulators are not accessible to the user. SINAD was achieved. With the 3.6kΩ resistor, sensitivity was 200 Φ Q = 100 175 Q = 80 Q = 60 150 Q = 20 125 Q = 10 100 75 50 25 0 0.95 0.975 1.0 1.025 1.05 SR00322 Figure 12. Phase vs Normalized IF Frequency 1 1 1 1997 Nov 07 11 Philips Semiconductors Product specification High performance low power FM IF system SO16: plastic small outline package; 16 leads; body width 3.9 mm 1997 Nov 07 12 SA604A SOT109-1 Philips Semiconductors Product specification High performance low power FM IF system SA604A DEFINITIONS Data Sheet Identification Product Status Definition Objective Specification Formative or in Design This data sheet contains the design target or goal specifications for product development. Specifications may change in any manner without notice. Preliminary Specification Preproduction Product This data sheet contains preliminary data, and supplementary data will be published at a later date. Philips Semiconductors reserves the right to make changes at any time without notice in order to improve design and supply the best possible product. Product Specification Full Production This data sheet contains Final Specifications. Philips Semiconductors reserves the right to make changes at any time without notice, in order to improve design and supply the best possible product. Philips Semiconductors and Philips Electronics North America Corporation reserve the right to make changes, without notice, in the products, including circuits, standard cells, and/or software, described or contained herein in order to improve design and/or performance. Philips Semiconductors assumes no responsibility or liability for the use of any of these products, conveys no license or title under any patent, copyright, or mask work right to these products, and makes no representations or warranties that these products are free from patent, copyright, or mask work right infringement, unless otherwise specified. Applications that are described herein for any of these products are for illustrative purposes only. Philips Semiconductors makes no representation or warranty that such applications will be suitable for the specified use without further testing or modification. LIFE SUPPORT APPLICATIONS Philips Semiconductors and Philips Electronics North America Corporation Products are not designed for use in life support appliances, devices, or systems where malfunction of a Philips Semiconductors and Philips Electronics North America Corporation Product can reasonably be expected to result in a personal injury. Philips Semiconductors and Philips Electronics North America Corporation customers using or selling Philips Semiconductors and Philips Electronics North America Corporation Products for use in such applications do so at their own risk and agree to fully indemnify Philips Semiconductors and Philips Electronics North America Corporation for any damages resulting from such improper use or sale. Copyright Philips Electronics North America Corporation 1997 All rights reserved. Printed in U.S.A. Philips Semiconductors 811 East Arques Avenue P.O. Box 3409 Sunnyvale, California 94088–3409 Telephone 800-234-7381 1997 Nov 07 13