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P82B715TD,118

P82B715TD,118

  • 厂商:

    NXP(恩智浦)

  • 封装:

    SOIC8_150MIL

  • 描述:

    IC REDRIVER I2C 1CH 400KHZ 8SO

  • 数据手册
  • 价格&库存
P82B715TD,118 数据手册
P82B715 I2C-bus extender Rev. 08 — 9 November 2009 Product data sheet 1. General description The P82B715 is a bipolar IC intended for application in I2C-bus and derivative bus systems. While retaining all the operating modes and features of the I2C-bus it permits extension of the practical separation distance between components on the I2C-bus by buffering both the data (SDA) and the clock (SCL) lines. The I2C-bus capacitance limit of 400 pF restricts practical communication distances to a few meters. Using one P82B715 at each end of a long cable (connecting Lx/Ly to Lx/Ly) reduces that cable’s loading on the linked I2C-buses by a factor of 10 and allows the total system capacitance load (all devices, cable, connectors, and traces or wires connected to the I2C-bus) to be around 3000 pF while the loading on each I2C-bus on the Sx/Sy sides remains below 400 pF. Longer cables or low-cost, general-purpose wiring may be used to link I2C-bus based modules without degrading noise margins. Multiple P82B715s can be connected together, linking their Lx/Ly ports, in a star or multi-point architecture as long as the total capacitance of the system is less than about 3000 pF and each bus at an Sx/Sy connection is well below 400 pF. This configuration, with the master and/or slave devices attached to the Sx/Sy port of each P82B715, has full multi-master communication capability. The P82B715 alone does not support voltage level translation, but it can be simply implemented using low cost transistors when required. There is no restriction on interconnecting the Sx/Sy I/Os, and, because the device output levels are always held within 100 mV of input drive levels, P82B715 is compatible with bus buffers that use voltage level offsets, e.g., PCA9511A, PCA9517, Sx/Sy side of P82B96. The lower VOL level and ability to operate with any master, slave or bus buffer is the primary advantage of the using the P82B715 for long distance buses at the disadvantage of not isolating bus capacitance like the P82B96 or PCA9600 are able to do. The primary disadvantage of the P82B96 and PCA9600 is that the static level offset needed to isolate bus capacitance does not allow these devices to operate with other bus buffers with special offset levels or with master/slaves that require a VIL lower than 0.8 V with noise margin. A proven quick design-in point-to-point/multi-point circuit (Figure 9) is included in Section 8.2 to allow rapid use of the P82B715 along with comparison waveforms so that the designer can clearly see the trade-offs between the P82B715 and the P82B96/PCA9600 and choose the type of device that is best for their application. 2. Features n Dual, bidirectional, unity voltage gain buffer with no external directional control required n Compatible with I2C-bus and its derivatives SMBus, PMBus, DDC, etc. n Logic signal levels may include (but not exceed) both supply and ground n Logic signal input voltage levels are output without change and are independent of VCC n ×10 impedance transformation, but does not change logic voltage levels P82B715 NXP Semiconductors I2C-bus extender n Supply voltage range 3 V to 12 V n Clock speeds to at least 100 kHz and 400 kHz when other system delays permit n ESD protection exceeds 2500 V HBM per Mil. Std 883C-3015.7 and 400 V MM per JESD22-A115 (I/Os have diodes to VCC and GND) n Latch-up testing is done to JEDEC Standard JESD78 which exceeds 100 mA 3. Applications n n n n n n Increase the total connected capacitance of an I2C-bus system to around 3000 pF Drive I2C-bus signals over long cables to approximately 50 meters or 3000 pF Drives ×10 lower impedance bus wiring for improved noise immunity Multi-drop distribution of I2C-bus signals using low cost twisted-pair cables AdvancedTCA radial IPMB architecture Driving 30 mA Fm+ devices from standard 3 mA parts 4. Ordering information Table 1. Ordering information[1] Type number Package Name Description Version P82B715PN DIP8 plastic dual in-line package; 8 leads (300 mil) SOT97-1 P82B715TD SO8 plastic small outline package; 8 leads; body width 3.9 mm SOT96-1 [1] For applications requiring lower voltage operation, or additional buffer performance, see application notes AN255, “I2C/SMBus repeaters, hubs and expanders” and AN10710, “Features and applications of the P82B715 I2C-bus extender”. 4.1 Ordering options Table 2. Ordering options Type number Topside mark Temperature range P82B715PN P82B715PN −40 °C to +85 °C P82B715TD P82B715 −40 °C to +85 °C P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 2 of 23 P82B715 NXP Semiconductors I2C-bus extender 5. Block diagram VCC P82B715 SDA BUFFER LDA SCL BUFFER LCL 002aad689 GND Fig 1. Block diagram of P82B715 6. Pinning information 6.1 Pinning P82B715TD P82B715PN n.c. 1 8 VCC Ly Lx 2 7 Ly 6 Sy Sx 3 6 Sy 5 n.c. GND 4 5 n.c. n.c. 1 8 VCC Lx 2 7 Sx 3 GND 4 002aad687 002aad686 Fig 2. Pin configuration for DIP8 Fig 3. Pin configuration for SO8 6.2 Pin description Table 3. Pin description Symbol Pin Description n.c. 1 not connected Lx 2 buffered bus, LDA or LCL Sx 3 I2C-bus, SDA or SCL GND 4 negative supply n.c. 5 not connected Sy 6 I2C-bus, SCL or SDA Ly 7 buffered bus, LCL or LDA VCC 8 positive supply P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 3 of 23 P82B715 NXP Semiconductors I2C-bus extender 7. Functional description The P82B715 is a dual bidirectional logic signal device having unity voltage gain in both directions, but ×10 current amplification in one direction that allows increasing the allowable I2C-bus system capacitance. It contains identical circuits for each I2C-bus signal and requires no external directional control. It uses unidirectional analog current amplification to increase the current sink capability of I2C-bus chips by a factor of 10 and to change the I2C-bus specification limit of 400 pF to a 4 nF system limit. This allows I2C-bus, or similar bus systems, to be extended over long distances using conventional cables and without degradation of system performance. P82B715 provides current amplification from its I2C-bus to its low-impedance or buffered bus. Whenever current is flowing out of Sx, into an I2C-bus chip driving the I2C-bus LOW, P82B715 will sink ten times that current into Lx to drive the buffered bus LOW (see Figure 4). To minimize interference and ensure stability, the current rise and fall times of the Lx drive amplifier are internally controlled. The P82B715 does not amplify signal currents flowing in the other direction, i.e., into Sx from the I2C-bus. The Sx pin is driven LOW by current flowing out of Lx to the driver of that buffered side. The buffered bus logic LOW voltage at Lx simply drives the I2C-bus at Sx LOW via the internal 30 Ω resistor. The buffer’s offset voltage (the difference between Sx and Lx) depends on the current flowing in the sense resistor so it will be very small when the bus currents are small, but it is guaranteed not to exceed 100 mV in either direction with full static I2C-bus loading. The unity voltage gain, with signal current amplification dependent on direction, preserves the multi-master, bidirectional, open-collector/open-drain, characteristic of any connected I2C-bus lines and provides these characteristics to the new low-impedance bus. Bus logic signal voltage levels will be clamped at (VCC + 0.7 V), but otherwise are independent of the supply voltage VCC. ISx = ILx ISx ILx = 10 × ISx ISx CURRENT SENSE I2C-bus Sx 9 × ISx Lx buffered bus 30 Ω VCC GND Fig 4. 002aad688 Equivalent circuit: one-half P82B715 7.1 Sx, Sy: I2C-bus SDA or SCL On the normal side, because the two buffer circuits in the P82B715 are identical, either the Sx or Sy input pins can be used as the I2C-bus SDA data line, or the SCL clock line. P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 4 of 23 P82B715 NXP Semiconductors I2C-bus extender 7.2 Lx, Ly: buffered bus LDA or LCL On the special low-impedance or buffered line side, the corresponding output at the Lx or Ly pins becomes the LDA data line or LCL clock line. 7.3 VCC, GND: positive and negative supply pins The power supply voltages at each P82B715 used in a system are normally nominally the same. If they differ by a significant amount, noise margin may be sacrificed as the bus HIGH level should not exceed the lowest of those supplies. 8. Application design-in information By using two (or more) P82B715 ICs, a sub-system can be built that retains the interface characteristics of a normal I2C-bus device so that the sub-system may be included in, or added onto, any I2C-bus or related system. The sub-system shown in Figure 5 features a low-impedance or buffered bus, capable of driving large wiring capacitance. The P82B715 will operate with a supply voltage from 3 V to 12.5 V but the logic signal levels at Sx/Lx are independent of the chip’s supply. They remain at the levels presented to the chip by the attached ICs. The maximum static I2C-bus sink current, 3 mA, flowing in either direction in the internal current sense resistor, causes a difference, or offset voltage, less than 100 mV between the bus logic LOW levels at Sx and Lx. This makes P82B715 fully compatible with all logic signal drivers, including TTL. The P82B715 cannot modify the bus logic signal voltage levels but it contains internal diodes connected between Lx/Sx and VCC that will conduct and limit the logic signal swing if the applied logic levels would have exceeded the supply voltage by more than 0.7 V. In normal applications external pull-up resistors will pull the connected buses up to the desired voltage HIGH level. Usually this will be the chip supply, VCC, but for very low logic voltages it is necessary to use a VCC of at least 3.3 V and preferably even higher. Note that full performance over temperature is only guaranteed from 4.5 V. Specification de-ratings apply when its supply voltage is reduced below 4.5 V. The absolute minimum VCC is 3 V. VCC VCC P82B715 P82B715 LDA SDA SDA 1/2 1/2 VCC VCC long cable LCL SCL 1/2 standard I2C-bus Fig 5. SCL 1/2 special buffered bus special buffered bus standard I2C-bus 002aad690 Minimum sub-system with P82B715 P82B715_8 Product data sheet I2C-BUS DEVICE © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 5 of 23 P82B715 NXP Semiconductors I2C-bus extender 8.1 I2C-bus systems As in standard I2C-bus systems, pull-up resistors are required to provide the logic HIGH levels on the buffered bus. (The standard open-collector configuration is retained.) The value and number of pull-up resistors used is flexible and depends on the system requirements and designer preferences. If P82B715 ICs are to be permanently connected into a system it could be configured with only one pull-up resistor on the buffered bus and none on the I2C-buses, but the system design will be simplified, and performance improved, by fitting separate pull-ups on each section of the bus. When a sub-system using P82B715 may be optionally connected to an existing I2C-bus system that already has a pull-up, then the effects of the sub-system pull-ups acting in parallel with the existing I2C-bus pull-up must be considered. 8.1.1 Pull-up resistance calculation When calculating the pull-up resistance values, the gain of the buffer introduces scaling factors which must be applied to the system components. In practical systems the pull-up resistance value is usually calculated to achieve the rise time requirement of the system. As an approximation, this requirement will be satisfied for a standard 100 kHz system if the time constant of the total system (product of the net resistance and net capacitance) is set to 1 microsecond or less. In systems using P82B715s, the most convenient way to achieve the total system rise time requirement is by considering each bus node separately. Each of the I2C-bus nodes, and the buffered bus node, is designed by selecting its pull-up resistor to provide the required rise time by setting its time constant (product of the pull-up resistance and load capacitance) equal to the I2C-bus rise time requirement. If each node complies, then the system requirement will also be met with a small safety margin. This arrangement, using multiple pull-ups as in Figure 6, provides the best system performance and allows stand-alone operation of individual I2C-buses if parts of the extended system are disconnected or re-connected. For each bus section the pull-up resistor for a Standard-mode system is calculated as shown in Equation 1: 1 µs R = ----------------------------------------------------C device + C wiring (1) Where: C device = sum of any connected device capacitances, and C wiring = total wiring and stray capacitance on the bus section. Remark: The 1 µs is an approximation, with a safety factor, to the theoretical time-constant necessary to meet the Standard-mode 1 µs bus rise time specification in a system with variable logic thresholds where the CMOS limits of 30 % and 70 % of VCC apply. The actual RC requirement can be shown to be 1.18 µs. For a Fast-mode system, and the same safety margin, replace the 1 µs with its 300 ns requirement. If these capacitances cannot be measured or calculated then an approximation can be made by assuming that each device presents 10 pF of load capacitance and 10 pF of trace capacitance and that cables range from 50 pF to 100 pF per meter. If only a single pull-up must be used then it must be placed on the buffered bus (as R2 in Figure 6) and the associated total system capacitance calculated by combining the individual bus capacitances into an equivalent capacitive loading on the buffered bus. P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 6 of 23 P82B715 NXP Semiconductors I2C-bus extender This equivalent capacitance is the sum of the capacitance on the buffered bus plus 10 times the sum of the capacitances on all the connected I2C-bus nodes. The calculated value should not exceed 4 nF. The single buffered bus pull-up resistor is then calculated to achieve the rise time requirement and it then provides the pull-up for the buffered bus and for all other connected I2C-bus nodes included in the calculation. VCC = 5 V R1 SDA R2 Sx Lx R3 Lx Sx Ly Sy SDA buffered bus I2C-bus 1 SCL Sy Ly I2C-bus 2 SCL VCC = 5 V R4 Lx Sx Ly Sy SDA I2C-bus 3 SCL 002aad691 Fig 6. Single pull-up on buffered bus and multiple pull-up option 8.1.2 Calculating static bus drive currents Figure 6 shows three P82B715s connected to a common buffered bus. The associated bus capacitances are omitted for clarity and we assume the pull-up resistors have been selected to give RC products equal to the bus rise time requirement. An I2C-bus chip connected at I2C-bus 1 and holding the SDA bus LOW must sink the current flowing in its local pull-up R1 plus, with assistance from the P82B715, the currents in R2, R3 and R4. When I2C-bus 1 is LOW, the resistors R3 and R4 act to pull the bus nodes I2C-bus 2 and I2C-bus 3, and their corresponding Sx pins, to a voltage higher than the voltage at their Lx pins (which are LOW) so their buffer amplifiers will be inactive. The SDA at Sx of I2C-bus 2 and I2C-bus 3 is pulled LOW by the LOW at Lx via the internal 30 Ω resistor that links Lx to Sx. So the effective current that must be sunk by the P82B715 buffer on I2C-bus 1, at its Lx pin, is the sum of the currents in R2, R3 and R4. The Sx current that must be sunk by an I2C-bus chip at I2C-bus 1, due to the buffer gain action, is 1⁄10 of the Lx current. So the effective pull-up, determining the current to be sunk by an I2C-bus chip at I2C-bus 1, is R1 in parallel with resistors 10 times the values of R2, R3 and R4. If R1 = R3 = R4 = 10 kΩ, and R2 = 1 kΩ, the effective pull-up load at I2C-bus 1 is 10 kΩ || 10 kΩ || 100 kΩ || 100 kΩ = 4.55 kΩ. (‘||’ means ‘in parallel with’.) The same calculation applies for I2C-bus 2 or I2C-bus 3. To calculate the current sunk by the Lx pin of the buffer at I2C-bus 1, note that the current in R1 is sunk directly by the IC at I2C-bus 1. The buffer therefore sinks only the currents flowing in R2, R3, and R4 so the effective pull-up is R2 in parallel with R3 and R4. In this example that is 1 kΩ || 10 kΩ || 10 kΩ = 833 Ω. For a 5.5 V supply and 0.4 V LOW, that means the buffer is sinking 16.3 mA. P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 7 of 23 P82B715 NXP Semiconductors I2C-bus extender The P82B715 has a static sink rating of 30 mA at Lx. The requirement is that the pull-up on the buffered bus, in parallel with all other pull-ups that it is indirectly pulling LOW on Sx pins of other P82B715 ICs, will not cause this 30 mA limit to be exceeded. The minimum pull-up resistance in a 5 V ± 10 % system is 170 Ω. The general requirement is given in Equation 2: V CC ( max ) – 0.4 V ------------------------------------------ < 30 mA R PU (2) Where: RPU = parallel combination of all pull-up resistors driven by the Lx pin of the P82B715. Figure 7 shows calculations for an expanded Standard-mode I2C-bus with 3 nF of cable capacitance. local bus proposed bus expansion VCC 5V R1 I2C-BUS R2 Sx I2C-BUS R3 SDA Lx SDA LDA Lx Sx SDA I2C-BUS 3 nF = cable wiring capacitance GND 0V effective capacitance local bus I2C-bus devices effective capacitance at common Lx node effective capacitance remote I2C-bus devices 2 × I2C-bus devices strays P82B715 20 pF 20 pF 10 pF wiring capacitance 3000 pF 1 × I2C-bus devices strays P82B715 10 pF 10 pF 10 pF total capacitance 50 pF total capacitance 3000 pF total capacitance 30 pF local I2C-bus pull-up R1 = 1 µs 50 pF = 20 kΩ buffered bus pull-up R2 = 1 µs 3000 pF = 330 Ω remote I2C-bus pull-up R3 = 1 µs 30 pF = 33 kΩ 002aad692 Fig 7. Typical loading calculation: adding an extension bus with P82B715 P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 8 of 23 P82B715 NXP Semiconductors I2C-bus extender 3.3 V R1 ShMM Sx BUFFER R3 R2 Lx Lx FRU 1 Sx BUFFER C1 1 C2 R3 common Lx node Lx Sx FRU 2 radial traces BUFFER 2 µC C3 R3 Lx µC C3 FRU 16 Sx BUFFER 16 µC C3 Calculations to ensure rise time is met on each bus section: effective capacitance at ShMM buffer effective capacitance at common Lx node effective capacitance at average radial trace ShMM buffer strays P82B715 10 pF 20 pF 10 pF 17 × P82B715 trace capacitance 170 pF 30 pF 1 × FRU radial trace/connector P82B715 25 pF 125 pF 10 pF total capacitance C1 40 pF total capacitance C2 200 pF total capacitance C3 160 pF ShMM buffer pull-up R1 = 1 µs 40 pF = 25 kΩ Lx common pull-up R2 = 1 µs 200 pF = 5 kΩ radial trace pull-up R3 = 1 µs 160 pF = 6.2 kΩ 002aad708 Calculation of static loading at ShMM buffer and each FRU: Loading on ShMM buffer = R1 || {10 (R2 || R3/16)} = 3.5 kΩ Loading on each FRU = R3 || {10 (R1 || R2 || R3/15)} = 3.76 kΩ Fig 8. Typical arrangement and calculations for an IPMB analog radial shelf Figure 8 shows P82B715 in an analog radial IPMB shelf application. In this example the total system capacitance is 2800 pF, but it is distributed over 18 different bus sections and no section has a capacitance greater than 200 pF. If every individual bus section is designed to rise at least as fast as the IPMB requirement, then when any driver releases the bus, all bus sections will rise together and no amplifiers in the P82B715s will be activated or, if one is activated, it can only slow the system bus rise to its own rate and that has been designed to meet the requirement. It is then only necessary to calculate the equivalent static bus pull-up loading and to ensure that it exceeds the specification requirement. The calculated loadings meet the requirements. Note that in this example only one of the four IPMB lines is shown and the usual switching arrangements for isolating or cross-connecting bus lines are not shown. The typical offset (increase in the bus LOW level) measured between any two Sx points in this system is below 100 mV. P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 9 of 23 P82B715 NXP Semiconductors I2C-bus extender 8.2 Quick design-in point-to-point/multi-point circuit information for 5 V bus With many variables (cable length/capacitance, local capacitive loading on each I2C-bus, bus voltages, and bus speed), optimizing a design can be complex and requires significant study of the application note information. The following circuit and simplified approach has been checked to provide adequate performance in the typical 100 kHz application and can be easily implemented by just using the values and circuit shown for either point-to-point application, up to 30 meters long, or in multiple point applications if additional nodes need to be added along the way. 5V 5V 4.7 kΩ SDA I2C-BUS MASTER SCL µC 4.7 kΩ 470 Ω Sx 470 Ω 470 Ω 20 meter Cat5e twisted pair cable 470 Ω Lx Lx Ly Ly P82B715 Sy 4.7 kΩ 4.7 kΩ Sx SDA Sy SCL P82B715 5V1 I2C-BUS SLAVE 5V1 optional ESD protection optional ESD protection 5V optional ESD protection 4.7 kΩ 4.7 kΩ Sx SDA Sy I2C-BUS SCL SLAVE Lx P82B715 Ly 5V1 002aad817 Remark: Cable bus pull-ups only fitted at the cable ends, not fitted to modules connected along cable. Fig 9. Quick design-in point-to-point/multi-point circuit for 5 V bus Specific information on this circuit implementation: • The pull-up on each I2C-bus is (VCC − 0.4 V) / 1 mA = 4.6 kΩ, using 4.7 kΩ as the nearest usual value. • The net pull-up on the cable bus can be (VCC − 0.5 V) / (21 − n) mA where n = total number of P82B715 modules on the cable. When there are only two modules, one each end of the cable, the pull-up = (4.5 / 19) = 237 Ω. Make the pull-ups at each end of the cable equal. Signalling is bidirectional so there is no advantage optimizing for any one direction. The pull-up at each end will be 474 Ω, using 470 Ω as the nearest usual value. • The 100 kHz rise time requirement is 1 µs. Meeting this requires the product of the bus capacitance and pull-up resistor on each bus section to be less than 1.18 µs. That provides one capacitance limit. With 4.7 kΩ pull-ups the I2C-bus limit is 250 pF each, while the 235 Ω sets a cable bus limit at 5000 pF. P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 10 of 23 P82B715 NXP Semiconductors I2C-bus extender • The 300 ns bus fall time, and the Standard-mode I2C-bus limit specification limit of 400 pF, must also be observed. If the 400 pF limit is observed the fall time limit will be met. Allocate about 1⁄3 of this 400 pF limit, or 133 pF, to each I2C-bus leaving 2⁄3, or 266 pF, for the cable bus loading as it will appear at the Sx/Sy pins. The ×10 gain of P82B715 allows the loading at Lx/Ly to be 10 times the load at Sx/Sy, so 2660 pF maximum. The loading at Lx/Ly due to the other standard buses is 133 pF each. For just one remote module the cable capacitance may then be up to (2660 − 133) = 2530 pF. For typical twisted pair or flat cables, as used for telephony or Ethernet (Cat5e) wiring, that capacitance is around 50 pF to 70 pF / meter so the cable could, in theory, be up to 50 m long. From practical experience, 30 m has proven a safe cable length to be driven in this simple way, up to 100 kHz, with the values shown. Longer distances and higher speeds are possible but require more careful design. • If there are severe EMI/ESD tests to be passed then large clamp diodes can be fitted on the cable bus at each module to VCC and to ground. They may be diodes rated for this ESD application, or simply large rectifiers (1N4000). The low-impedance bus easily accommodates their relatively large capacitance. The P82B715 does not provide any isolation between Lx and Sx, so this clamping method provides the best protection for the lower voltage I2C-bus parts. The VCC supply should be bypassed using low-impedance capacitors. Zeners may be fitted to prevent the supply rising due to rectification during very large interference. 8.3 Comparison of P82B715 versus P82B96 in the quick design-in point-to-point/multi-point circuit The lower VOL level and ability to operate with any master, slave or bus buffer is the primary advantage of the using the P82B715 for long distance buses at the disadvantage of not isolating bus capacitance like the P82B96 or PCA9600 are able to do. The primary disadvantage of the P82B96 and PCA9600 is that the static level offset needed to isolate bus capacitance does not allow these devices to operate with other bus buffers with special offset levels or with master/slaves that require a VIL lower than 0.8 V with noise margin. Waveforms using the circuit shown in Figure 9 are shown in Figure 10 using the P82B715 and Figure 11 using the P82B96 so that the designer can clearly see these trade-offs and choose the type of device that is best for their application. 002aad818 7 voltage (V) 5 SDA SDA 3 SCL SDA 1 SCL SCL −1 0 4 8 12 16 20 time (µs) Fig 10. Clock and data signal output at Sx/Sy from a system with P82B715 at each end of a 20 m cable P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 11 of 23 P82B715 NXP Semiconductors I2C-bus extender Figure 10 shows the I2C-bus waveforms from the long distance line as seen by the slave on the P82B715 Sx/Sy I/O. Notice that the offset is small and the static levels remain under 0.4 V. Coupling of SDA to SCL is negligible when SCL is LOW but slight cross-coupling of SCL to SDA is visible when SDA is HIGH and therefore higher impedance. The waveforms are very clean and will easily support all available I2C-bus masters and slaves. 002aad819 7 voltage (V) 5 SDA 3 SDA SCL SCL SCL SDA 1 SCL −1 0 4 8 12 16 20 time (µs) Fig 11. Clock and data signal output to a slave from Sx/Sy of a P82B96 replacing one of the P82B715s Figure 11 shows the waveforms on the Sx/Sy I/O as seen by the slave when a P82B96 is substituted. P82B96 uses a static level offset on the slave side to isolate noise and loadings on either side of this device. The nominal offset is 0.8 V and that VOL may create worst-case design tolerance problems with slave devices that do not use I2C-bus switching levels, for example TTL levels. It also precludes operation with other bus buffers using special non-compliant I2C-bus levels. The P82B96 does not actually interfere with the operation of compliant I2C-bus devices down to at least 2.7 V supply or even with TTL devices (that switch around 1.4 V). It only causes a theoretical worst case design tolerance problem because TTL devices have a worst case 0.8 V requirement. A TTL designer must center the actual switch point between the two specified limits, 0.8 V and 2.1 V, so in reality it cannot ever approach the problem 0.8 V theoretical limit. The PCA9600 is an improved version of the P82B96 offering 1 MHz operation and lower, more closely controlled VOL on the Sx and Sy pins. P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 12 of 23 P82B715 NXP Semiconductors I2C-bus extender 9. Limiting values Table 4. Limiting values In accordance with the Absolute Maximum Rating System (IEC 60134). Symbol Parameter Conditions supply voltage VCC I2C-bus, Max Unit −0.3 +12 V [1] 0 VCC V [1] 0 VCC V Vbus voltage range Vbuff voltage range buffered bus I DC current (any pin) - 60 mA Ptot total power dissipation - 300 mW Tstg storage temperature −55 +125 °C Tamb ambient temperature −40 +85 °C [1] SCL or SDA Min [1] operating Voltages with respect to GND. The bus voltages quoted are DC voltages and are allowed to be exceeded during any negative transient undershoot that may be generated by normal operation of P82B715, P82B96 or PCA9600 when any of those parts are driving long PCB traces, wiring or cables. The Lx/Sx pins have internal protective diodes to GND that will conduct when the applied bus voltage exceeds approximately −0.6 V and these diodes will limit the amplitude of the negative undershoot. If required, fitting additional Schottky diodes such as BAT54A at Sx/Sy may be used to further ensure any undershoot at these pins does not cause conduction of the diodes inside other ICs connected to Sx/Sy. 10. Characteristics Table 5. Characteristics Tamb = 25 °C; VCC = 5 V; unless otherwise specified. Symbol Parameter Conditions Min Typ Max Unit 4.5 - 12 V - 14 - mA VCC = 12 V - 15 - mA both I2C-bus inputs LOW; both buffered outputs sinking 30 mA - 22 - mA 3 - - mA 30 - - mA VCC > 3 V; VLx, VLy LOW = 0.4 V to 1.5 V; ISx, ISy sinking on I2C-bus < −4 mA 24 - - mA VCC > 3 V; VLx, VLy LOW = 1.5 V to VCC; ISx, ISy sinking on I2C-bus = −7 mA 24 - - mA Power supply VCC supply voltage ICC supply current operating [1] Drive currents ISx, ISy output sink on I2C-bus VCC > 3 V; VSx, VSy LOW = 0.4 V; VLx, VLy LOW on buffered bus = 0.3 V; ILx, ILy = −3 mA ILx, ILy output sink on buffered bus VLx, VLy LOW = 0.4 V; VSx, VSy LOW on I2C-bus = 0.3 V [2] Derated dynamic drive currents for VCC < 4.5 V[1] ILx, ILy output sink on buffered bus P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 13 of 23 P82B715 NXP Semiconductors I2C-bus extender Table 5. Characteristics …continued Tamb = 25 °C; VCC = 5 V; unless otherwise specified. Symbol Parameter Conditions Min Typ Max Unit - - −3 mA - - −3 mA - - 200 µA 8 10 13 Input currents input current from I2C-bus ISx, ISy ILx, ILy sink on buffered bus = 30 mA [2] ILx, ILy input current from buffered bus VCC > 3 V; ISx, ISy sink on I2C-bus = 3 mA ILx, ILy leakage current on buffered bus VCC = 3 V to 12 V; VLx, VLy = VCC and VSx, VSy = VCC Impedance transformation Zin/Zout input/output impedance VSx < VLx and the buffer is active; ILx sinking 30 mA on buffered bus Buffer delay times trise/fall delay time delay to VLx voltage crossing 0.5VCC for input drive ISx to VLx current step ISx at Sx ISy to VLy see Figure 12; RLx pull-up = 270 Ω; no capacitive load; VCC = 5 V [3] - 250 - ns trise/fall delay buffer time delay of switching VLx to VSx edges between VLx input and VLy to VSy VSx output RSx pull-up = 4700 Ω; no capacitive load; VCC = 5 V [4] - 0 - ns [1] Operation with reduced performance is possible down to 3 V. Typical static sinking performance is not degraded at 3 V, but the dynamic sink currents while the output is being driven through 0.5VCC are reduced and can increase fall times. Timing-critical designs should accommodate the guaranteed minimums. [2] Buffer is passive in this test. The Sx/Sy sink current flows via an internal resistor to the driver connected at the Lx/Ly I/O. [3] A conventional input-output delay will not be observed in the Sx/Lx voltage waveforms because the input and output pins are internally tied with a 30 Ω resistor so they show equal logic voltage levels, to within 100 mV. When connected in an I2C-bus system, an Sx/Sy input pin cannot rise/fall until the buffered bus load at the output pin has been driven by the internal amplifier. This test measures the bus propagation delay caused to falling or rising voltages at the Lx/Ly output (as well as the Sx/Sy input) by the amplifier’s response time. The figure given is measured with a drive current as shown in Figure 12. Because this is a dynamic bus test in which a corresponding bus driving IC has an output voltage well above 0.4 V, 6 mA is used instead of the static 3 mA. [4] The signal path Lx to Sx and Ly to Sy is passive via the internal 30 Ω resistor. There is no amplifier involved and essentially no signal propagation delay. 11. Test information 5V 270 Ω 4.7 kΩ Sx input input current P82B715 Lx Lx 4.7 kΩ P82B715 5V Sx input and output voltage output 0V V V V I = 6 mA tdelay tdelay 002aad693 Fig 12. Test circuit for delay times P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 14 of 23 P82B715 NXP Semiconductors I2C-bus extender 12. Package outline DIP8: plastic dual in-line package; 8 leads (300 mil) SOT97-1 ME seating plane D A2 A A1 L c Z w M b1 e (e 1) b MH b2 5 8 pin 1 index E 1 4 0 5 10 mm scale DIMENSIONS (inch dimensions are derived from the original mm dimensions) UNIT A max. A1 min. A2 max. b b1 b2 c D (1) E (1) e e1 L ME MH w Z (1) max. mm 4.2 0.51 3.2 1.73 1.14 0.53 0.38 1.07 0.89 0.36 0.23 9.8 9.2 6.48 6.20 2.54 7.62 3.60 3.05 8.25 7.80 10.0 8.3 0.254 1.15 inches 0.17 0.02 0.13 0.068 0.045 0.021 0.015 0.042 0.035 0.014 0.009 0.39 0.36 0.26 0.24 0.1 0.3 0.14 0.12 0.32 0.31 0.39 0.33 0.01 0.045 Note 1. Plastic or metal protrusions of 0.25 mm (0.01 inch) maximum per side are not included. REFERENCES OUTLINE VERSION IEC JEDEC JEITA SOT97-1 050G01 MO-001 SC-504-8 EUROPEAN PROJECTION ISSUE DATE 99-12-27 03-02-13 Fig 13. Package outline SOT97-1 (DIP8) P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 15 of 23 P82B715 NXP Semiconductors I2C-bus extender SO8: plastic small outline package; 8 leads; body width 3.9 mm SOT96-1 D E A X c y HE v M A Z 5 8 Q A2 A (A 3) A1 pin 1 index θ Lp 1 L 4 e detail X w M bp 0 2.5 5 mm scale DIMENSIONS (inch dimensions are derived from the original mm dimensions) UNIT A max. A1 A2 A3 bp c D (1) E (2) e HE L Lp Q v w y Z (1) mm 1.75 0.25 0.10 1.45 1.25 0.25 0.49 0.36 0.25 0.19 5.0 4.8 4.0 3.8 1.27 6.2 5.8 1.05 1.0 0.4 0.7 0.6 0.25 0.25 0.1 0.7 0.3 inches 0.069 0.010 0.057 0.004 0.049 0.01 0.019 0.0100 0.014 0.0075 0.20 0.19 0.16 0.15 0.05 0.01 0.01 0.004 0.028 0.012 0.244 0.039 0.028 0.041 0.228 0.016 0.024 θ 8o o 0 Notes 1. Plastic or metal protrusions of 0.15 mm (0.006 inch) maximum per side are not included. 2. Plastic or metal protrusions of 0.25 mm (0.01 inch) maximum per side are not included. REFERENCES OUTLINE VERSION IEC JEDEC SOT96-1 076E03 MS-012 JEITA EUROPEAN PROJECTION ISSUE DATE 99-12-27 03-02-18 Fig 14. Package outline SOT96-1 (SO8) P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 16 of 23 P82B715 NXP Semiconductors I2C-bus extender 13. Soldering of SMD packages 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”. 13.1 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. 13.2 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 SnPb soldering 13.3 Wave soldering Key characteristics in wave soldering are: • 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 P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 17 of 23 P82B715 NXP Semiconductors I2C-bus extender 13.4 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 15) than a SnPb 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 6 and 7 Table 6. 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 7. 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 15. P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 18 of 23 P82B715 NXP Semiconductors I2C-bus extender maximum peak temperature = MSL limit, damage level temperature minimum peak temperature = minimum soldering temperature peak temperature time 001aac844 MSL: Moisture Sensitivity Level Fig 15. Temperature profiles for large and small components For further information on temperature profiles, refer to Application Note AN10365 “Surface mount reflow soldering description”. 14. Soldering of through-hole mount packages 14.1 Introduction to soldering through-hole mount packages This text gives a very brief insight into wave, dip and manual soldering. Wave soldering is the preferred method for mounting of through-hole mount IC packages on a printed-circuit board. 14.2 Soldering by dipping or by solder wave Driven by legislation and environmental forces the worldwide use of lead-free solder pastes is increasing. Typical dwell time of the leads in the wave ranges from 3 seconds to 4 seconds at 250 °C or 265 °C, depending on solder material applied, SnPb or Pb-free respectively. The total contact time of successive solder waves must not exceed 5 seconds. The device may be mounted up to the seating plane, but the temperature of the plastic body must not exceed the specified maximum storage temperature (Tstg(max)). If the printed-circuit board has been pre-heated, forced cooling may be necessary immediately after soldering to keep the temperature within the permissible limit. 14.3 Manual soldering Apply the soldering iron (24 V or less) to the lead(s) of the package, either below the seating plane or not more than 2 mm above it. If the temperature of the soldering iron bit is less than 300 °C it may remain in contact for up to 10 seconds. If the bit temperature is between 300 °C and 400 °C, contact may be up to 5 seconds. P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 19 of 23 P82B715 NXP Semiconductors I2C-bus extender 14.4 Package related soldering information Table 8. Suitability of through-hole mount IC packages for dipping and wave soldering Package Soldering method Dipping Wave CPGA, HCPGA - suitable DBS, DIP, HDIP, RDBS, SDIP, SIL suitable suitable[1] PMFP[2] - not suitable [1] For SDIP packages, the longitudinal axis must be parallel to the transport direction of the printed-circuit board. [2] For PMFP packages hot bar soldering or manual soldering is suitable. 15. Abbreviations Table 9. Abbreviations Acronym Description AdvancedTCA Advanced Telecom Computing Architecture CMOS Complementary Metal-Oxide Semiconductor DDC Data Display Channel EMI ElectroMagnetic Interference ESD ElectroStatic Discharge FRU Field Replaceable Unit HBM Human Body Model I2C-bus Inter-Integrated Circuit bus I/O Input/Output IC Integrated Circuit IPMB Intelligent Platform Management Bus MM Machine Model PMBus Power Management Bus RC Resistor-Capacitor network ShMM Shelf Management Module SMBus System Management Bus TTL Transistor-Transistor Logic P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 20 of 23 P82B715 NXP Semiconductors I2C-bus extender 16. Revision history Table 10. Revision history Document ID Release date Data sheet status Change notice Supersedes P82B715_8 20091109 Product data sheet - P82B715_7 Modifications: • Table 4 “Limiting values”, Table note [1]: added 2nd paragraph. P82B715_7 20080529 Product data sheet - P82B715_6 P82B715_6 (9397 750 12452) 20031202 Product data ECN 853-2240 01-A14516 of 14 Nov 2003 P82B715_5 P82B715_5 (9397 750 11094) 20030220 Product data ECN 853-2240 29410 of 22 Jan 2003 P82B715_4 P82B715_4 (9397 750 08163) 20010306 Product data ECN 853-2240 25757 of 06 Mar 2001 P82B715_3 P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 21 of 23 P82B715 NXP Semiconductors I2C-bus extender 17. Legal information 17.1 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. 17.2 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. 17.3 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 an 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. Export control — This document as well as the item(s) described herein may be subject to export control regulations. Export might require a prior authorization from national authorities. 17.4 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. 18. Contact information For more information, please visit: http://www.nxp.com For sales office addresses, please send an email to: salesaddresses@nxp.com P82B715_8 Product data sheet © NXP B.V. 2009. All rights reserved. Rev. 08 — 9 November 2009 22 of 23 P82B715 NXP Semiconductors I2C-bus extender 19. Contents 1 2 3 4 4.1 5 6 6.1 6.2 7 7.1 7.2 7.3 8 8.1 8.1.1 8.1.2 8.2 8.3 9 10 11 12 13 13.1 13.2 13.3 13.4 14 14.1 14.2 14.3 14.4 15 16 17 17.1 17.2 17.3 17.4 General description . . . . . . . . . . . . . . . . . . . . . . 1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 Ordering information . . . . . . . . . . . . . . . . . . . . . 2 Ordering options . . . . . . . . . . . . . . . . . . . . . . . . 2 Block diagram . . . . . . . . . . . . . . . . . . . . . . . . . . 3 Pinning information . . . . . . . . . . . . . . . . . . . . . . 3 Pinning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 Pin description . . . . . . . . . . . . . . . . . . . . . . . . . 3 Functional description . . . . . . . . . . . . . . . . . . . 4 Sx, Sy: I2C-bus SDA or SCL . . . . . . . . . . . . . . . 4 Lx, Ly: buffered bus LDA or LCL. . . . . . . . . . . . 5 VCC, GND: positive and negative supply pins . . 5 Application design-in information . . . . . . . . . . 5 I2C-bus systems . . . . . . . . . . . . . . . . . . . . . . . . 6 Pull-up resistance calculation . . . . . . . . . . . . . . 6 Calculating static bus drive currents . . . . . . . . . 7 Quick design-in point-to-point/multi-point circuit information for 5 V bus . . . . . . . . . . . . . 10 Comparison of P82B715 versus P82B96 in the quick design-in point-to-point/ multi-point circuit. . . . . . . . . . . . . . . . . . . . . . . 11 Limiting values. . . . . . . . . . . . . . . . . . . . . . . . . 13 Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . 13 Test information . . . . . . . . . . . . . . . . . . . . . . . . 14 Package outline . . . . . . . . . . . . . . . . . . . . . . . . 15 Soldering of SMD packages . . . . . . . . . . . . . . 17 Introduction to soldering . . . . . . . . . . . . . . . . . 17 Wave and reflow soldering . . . . . . . . . . . . . . . 17 Wave soldering . . . . . . . . . . . . . . . . . . . . . . . . 17 Reflow soldering . . . . . . . . . . . . . . . . . . . . . . . 18 Soldering of through-hole mount packages . 19 Introduction to soldering through-hole mount packages . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 Soldering by dipping or by solder wave . . . . . 19 Manual soldering . . . . . . . . . . . . . . . . . . . . . . 19 Package related soldering information . . . . . . 20 Abbreviations . . . . . . . . . . . . . . . . . . . . . . . . . . 20 Revision history . . . . . . . . . . . . . . . . . . . . . . . . 21 Legal information. . . . . . . . . . . . . . . . . . . . . . . 22 Data sheet status . . . . . . . . . . . . . . . . . . . . . . 22 Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 Disclaimers . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 Trademarks . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 18 19 Contact information . . . . . . . . . . . . . . . . . . . . 22 Contents. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 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. 2009. All rights reserved. For more information, please visit: http://www.nxp.com For sales office addresses, please send an email to: salesaddresses@nxp.com Date of release: 9 November 2009 Document identifier: P82B715_8
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