MMO-6RF中文资料

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Nor does TI warrant or represent that any license, either express or implied, is granted under any patent right, copyright, mask work right, or other intellectual property right of TI covering or relating to any combination, machine, or process in which such products or services might be or are used.INDEXIMPORTANT NOTICE1♦Overview3♦Features3♦TIRIS System Configuration (Schematic Diagram)3♦Internal Block Diagram and Pin Assignment4♦Description of Pins5♦Functions and Operation61.G eneral62.S ending Mode63.R eceiving Mode7♦Electrical Specifications91.A bsolute Maximum Rating92.R ecommended Operating Conditions93.E lectrical Features under Recommended Operating Conditions♦Input-Output Specifications101.T ransmitter Signal I/O Timing102.R eceiver Signal I/O Timing10♦Dimensional Outline Drawing - 16-pin SOP12♦Applied Circuit Configuration - Example13♦Typical Transmitter Circuit Configuration14♦Typical Receiver Circuit Configuration15♦Typical Antenna Circuit Configuration16♦Precautions for Mounting and Actual Use171.P ower Supply Line172.W iring for Antenna Circuit18♦Package19!OverviewR I-RFM-006A is a CMOS-technology based RF-module IC which integrates all transmitter-receiver functions required for constructing a TIRIS Read-Write System into one single chip.R I-RFM-006A consists of a transmitter signal control logic which generates signals for power transmission and for sending the data you wrote to a remote TIRIS transponder, and a receiver which amplifies and demodulates frequency shift keyed (FSK) signals received from this transponder.T herefore, RI-RFM-006A is beneficially usable for constructing, in particular, a compact TIRIS Read-Write System at a reduced cost. Furthermore, demodulation of the FSK signals received in its receiver from a remote transponder is entirely digitized; this completely eliminates the need of regulations and lessens the number of required external parts, thus enhancing the operational reliability of the system.!FeaturesT he TIRIS RF-Module IC for Automotive Application, RI-RFM-006A, provides the following features amongst others:•It incorporates a transmitter circuit with power selector and an open drain transmission power pre-driver.•Also incorporated are a receiver signal amplifier and a digitized FSK signal demodulator.•I/O specifications: Conform to TIRIS standard RF-module specifications, with available signals of TXCT-, RXDT-(*) and RXCK only.(*) For RXDT- signals, this RF-module has a reverse polarity in relation to TIRIS standard RF-modules. See the section “Description of Pins” for more information.•Operating supply voltage: 4.5 V to 5.5 V•Operating temperature range: -40 °C to +85 °C•Package: 16-pin SO package•Structure: CMOS process!TIRIS System Configuration (Schematic Diagram)T IRIS System Configuration! Internal Block Diagram and Pin AssignmentA3OP A3INA2OP A2INA1OP A1INTXLO TXHIOSCIOSCOGND VCCTPC TXCT-RXDT-RXCKN ame I /O FunctionN ameI /O FunctionA 3OP C MOS INVERTER-3/FSK SIGNAL OUTPUT O SCI O SCILLATOR INPUT(17.1776MHz typ.) A 3INC MOS INVERTER-3/FSK SIGNAL INPUT O SCOO SCILLATOR OUTPUT A 2OPC MOS INVERTER-2 OUTPUT G NDG ND(POWER SUPPLY) A 2INC MOS INVERTER-2 INPUT V CCV CC(POWER SUPPLY) A 1OPC MOS INVERTER-1 OUTPUT T PCT X-POWER Hi/Lo SELECT SIG. INPUT A 1INC MOS INVERTER-1 INPUT T XCT-T X-OUTPUT CONTROL SIGNAL INPUT T XLOT X-OUTPUT(NCH OPEN DRAIN OUTPUT) R XDT-R X-DATA("L"="1","H"="0") OUTPUT T XHI T X-OUTPUT(PCH OPEN DRAIN OUTPUT) R XCKR X-DATA CLOCK OUTPUT!Description of PinsP in #S ignal I/O D escription1A3OP O S ignal output from CMOS inverter-3 amplifier; this pin is connected to theinternal FSK signal digital demodulator.2A3IN I S ignal input to CMOS inverter-3 amplifier; if an external circuit is used toamplify FSK signals, the amplified signals are input through this pin.3A2OP O S ignal output from CMOS inverter-2 amplifier.4A2IN I S ignal input to CMOS inverter-2 amplifier.5A1OP O S ignal output from CMOS inverter-1 amplifier.6A1IN I I 16. Signal input to CMOS inverter-1 amplifier.7T XLO N egative opendrain output N egative level output of transmission signals; this output drives the n-channel MOSFET used as antenna driver.8T XHI P ositive opendrain output P ositive level output of transmission signals; this output drives the p-channel MOSFET used as antenna driver.9O SCI I S ignal input to 17.1776 MHz master clock oscillator.10O SCO O S ignal output from 17.1776 MHz master clock oscillator. 11G ND-N egative power supply.12V CC-P ositive power supply.13T PC I, w/pull-upresistor I nput of transmission power selection signals (High-Low). A Low level signal input through this pin substantially lowers the power during transmission.14T XCT-I, w/pull-upresistor I nput of transmission output control signals (Transmit-Receive Mode Selector). A Low level signal input through this pin outputs a transmission signal to either “TXLO/TXHI” pin while a High level signal input turns the mode to Receive and activates the internal FSK signal digital demodulator.15R XDT-O S erial output of demodulated FSK signal bit data. Negative level outputwhen the bit data received from the remote transponder is “1”, and positivelevel output when it is “0”.N ote: The RI-RFM-006A has a reverse polarity in relation to TIRISstandard RF-modules.16R XCK O S ynchronous clock output of demodulated FSK signal data; a clock signalsynchronized with the “RXDT-“ signal is output.!Function and Operation1.GeneralT his RF-module IC counts on two operating modes:S ending Mode - This mode is active when the “TXCT-“ pin is set to L-level. A remote TIRIS transponder can be charged up and ID code can be sent to that transponder in this mode.R eceiving Mode - This mode is active when the “TXCT-“ pin is set to H-level. FSK signals sent from a remote TIRIS transponder are received and demodulated in this mode.T herefore, by switching over these modes using an external controller, data communications with a TIRIS transponder can be made.N ote that this RF-module IC is exclusively designed to provide the user with a simple signal modulator-demodulator (modem) function for data communications with a remote TIRIS transponder, based on the appropriate data modulation-demodulation specifications. And therefore, it does not incorporate error detection, data allotment nor other similar data processing functions in terms of protocol and data formats.(*) In both transmit and receive modes, this RF-module IC modulates and demodulates signals by logical operation based on the incorporated master clock. This means that the modulating-demodulating performance characteristics of this IC are directly affected by the frequency accuracy and variation of its master clock (normal frequency is 17.1776 MHz). Therefore, the user is requested to select an oscillating element or an external clock which is compatible with the remote TIRIS transponder to be used (see the section describing the specifications “fexc”, “fL” and “fH”).2.Sending ModeI n the Sending Mode, the frequency of the IC master clock (normal value: 17.1776 MHz) is divided by 128. The resulting clock signal then has a frequency of 134.2 kHz (normal value). This resulting signal is output as a composite signal for “TXHI” and “TXLO” terminals (pins) to drive the MOSFET which is incorporated as an antenna resonance circuit driver, as illustrated below.W hen the IC is in the Receiving Mode, its “TXHI” terminal is fixed at positive level and the “TXLO” at high impedance. As a result, the output terminal “A” of the MOSFET used as an antenna resonance circuit driver is fixed at negative level.N ote that when the IC is in the Sending Mode, its “RXDT-“ terminal is always fixed at positive level and as a consequence, the IC’s FSK signal demodulator remains deactivated although data clock signals, which are transmitted at a frequency resulting from division of the “A3IN” terminal signal frequency by 16, are output to the “RXCK”.3.Receiving ModeI n the Receiving Mode, the frequency-shift-keyed data signals are sequentially digitized to discriminate their frequencies by binary notation (high-low) and demodulate them into bit strings consisting of bit data “1” and “0”.F or binary discrimination of signal frequencies between high and low, the frequency level of each FS-keyed signal is measured from its leading edge at the “A3OP” terminal through to the next leading edge by count of the internal master clock, as shown below. The threshold for this counted value (x in the diagram below) is fixed at 132; when the clock count is over 132, it results in a negative level output at the “RXDT-“ terminal (bit data ”1”), and when the clock count does not reach 132, a positive level output at the same terminal (bit data “0”), respectively.A s the normal frequency of the internal master clock is 17.1776 MHz, one clock count is equivalent to 130.133... kHz (17.1776 MHz divided by 132 = 130.133... kHz). Accordingly, a signal is identified as bit data “1” with the resulting negative level output at the “RXDT-“ terminal when the signal frequency at the “A3OP” terminal is 130.133... kHz or less, and it is identified as bit data “0” with the resulting positive level output at the “RXDT-“ terminal when the signal frequency at the “A3OP” terminal is over 130.133... kHz.A n additional feature is included to maximize the stability of the above-mentioned FSK signal demodulating system based on binary notation: the system incorporates a circuit which disables definition of an “RXDT-“ signal unless more than four consecutive FS-keyed signal waves are identified within the same frequency band during binary discrimination. This protects the once defined “RXDT-“ signal in the bit data form from being affected by sporadic events. For instance, even when its discrimination result is sporadically inverted due to some noise effects, it is not affected if only three or less consecutive FS-keyed signal waves are identified at the “A3OP” terminal. (See the diagram below.)N ote: For the timing between “A3OP” and “RXDT-“ signals, refer to the section describing“Input-Output Specifications”.T he signals demodulated through the above-mentioned process are sequentially output from the “RXDT-“Internal master clock Signals discriminated at A3OP terminalClock counts 1123456X X-1234567Internal frequency discriminating signalsSignal discriminatedat A3OP terminal RXDT- terminal output signalsDA TA VALID DA TA V ALIDterminal in bit strings (“1” or “0”). To delimit these continuous bit strings, clock signals are output from the “RXCK” terminal in synchronization with each bit data.I n normal operating conditions (when data communication can be properly performed between the RI-RFM-006A and a TIRIS transponder), each bit data group sent from the remote transponder is composed of sixteen consecutive signal waves belonging to the same frequency band (consisting of two wave groups, 134.2-kHz high and 123.2-kHz low in terms of normal values). Therefore, clock signals at a frequency resulting from a simple division of the “A3OP” terminal signal frequency by 16, are output from the “RXCK” terminal. Then, each “RXCK” clock signal is controlled for output so that its first transition falls after four consecutive “A3OP” signal waves from the “RXDT-“ signal change point. This enables an external controller to obtain the relevant bit data without fail provided that each “RXDT-“signal is fetched well timed with the first transition of each “RXCK” signal. (See the diagram below.)S ometimes at starting or during data receiving, some bit data group (composed of sixteen consecutive signal waves belonging to the same frequency band) may be affected by interference noise, this causing the number of its waves to vary and the consequent synchronous discrepancy between “RXDT-“ and “RXCK” signals. To correct this discrepancy, the sixteenth dividing counter of frequency incorporated in this RF-module IC for “RXCK” clock signal generation are always reset at the moment at which any internal demodulated bit data changes from “0” to “1” so that “RXCK” terminal signals are forcibly output at L-level with the timing shown below. This correction is made automatically regardless of whether or not receiving signals are properly input. (The frequency dividing counter is not reset at bit data change from “1” to “0”.)N ote: For details about timing among these signals, refer to the section describing “Input-Output Specifications”.A3OP terminal signal!Electrical SpecificationsA bsolute Maximum RatingSupply voltage(V CC)- 0.5 to 7.0V Input voltage range(V i)- 0.5 to 7.0V Output voltage range(V o)- 0.5 to 7.0V Input clamping current(Iik)± 20 mAOutput clamping current(V ok)± 20 mAOutput current(I out(V out=0 to V cc))± 25 mAOperating temperature(T A)- 40 to +85ºC Storage temperature(T stg)- 65 to +150ºCR ecommended Operating ConditionsR ecommended Operating ConditionsM IN MAX U NIT Supply voltage, VCC3.5 5.5V High-level input voltage, VIH 0.7Vcc V Low-level input voltage, VIL 0.2Vcc V Operating free-air temperature, TA-40 85°C E lectrical Characteristics (VCC=5.0V, TA=25°C)P ARAMETER C ONDITIONS M IN TYP MAX U NIT Vth Hysteresis voltage1.7VIOH High-level output current (TXHI)(A2OP,A3OP) (A1OP)V OH=3.7V 6.82073144m Am Au Au AIOL Low-level output current (TXLO)(A2OP,A3OP) (A1OP)V OL=0.5V -6.8-20-72-144m Am Au Au ACi Input capacitance7.4p FIcc Supply current35m AN ote: Unless otherwise specified, all the voltage values indicated above are those measured versus the “GND” pin of this RF-module IC.!Input-Output SpecificationsT ransmitter Signal I/O TimingTXCT-TX=I tem S ignal M in. Typical Max.U nitD elay time between TXCT- and TXtrailing edgest dl(TX)64T c(OSC)nSD elay time between TXCT- and TXleading edgest dh(TX)1T c(OSC)n ST X cycle time t c(TX)128T c(OSC)n ST X low level pulse duration t wl(TX) 64T c(OSC)n ST X high level pulse duration t wh(TX) 64T c(OSC)n SN ote:“Tc(osc)” denotes the master clock cycle of this RF-module IC and its normal value is specified at 56.3 ns (1/0.0171776). The same applies hereinafter. “TX” is defined as a composite signal of “TXLO” and “TXHI” signals.R eceiver Signal I/O TimingA3OPRXCKRXDT-I tem S ignal M in.Typical Max.U nitt c(A3OP)2T c(OSC)n SA3OP cycle time for normal FSK signaldemodulationt wh(A3OP)1T c(OSC)n SA3OP positive level pulse duration for normalFSK signal demodulationt c(A3OP)132T c(OSC)n SA3OP cycle time for negative level output ofRXDT- signal (bit data “1”)t dh(RXCK)1T c(OSC)n SD elay time between A3OP and RXCK leadingedgest dl(RXCK)1T c(OSC)n SD elay time between A3OP leading edge andRXCK trailing edgeR XCK cycle time t c(RXCK)16T c(A3)n SR XCK positive level pulse duration t wh(RXCK)8T c(A3)n St d(RXDT)16T c(A3)+1T c(OSC)n SD elay time from consecutive A3OP identicalsignal waves to definition of an RXDT- signalR XDT- positive/negative level duration, definite t w(RXDT)16T c(A3)n St s(RXDT)4T c(A3)-1T c(OSC)n SR XDT- signal setup time in relation to RXCKsignalt h(RXDT)4T c(A3)-1T c(OSC)n SR XDT-signal hold time in relation to RXCKsignalN ote:“Tc(A3)” denotes the signal cycle at the “A3OP” terminal and the above values are based on the condition that a bit data group composed of sixteen consecutive signal waves belonging to the same frequency band (sent from a remote TIRIS transponder in normal operating conditions) has been previously input; otherwise, the values shown in the table below shall apply.I tem S ignal M in. Typical Max.U nitt c(RXCK)9T c(A3)n SR XCK cycle time (except for normal signalreceiving)t wh(RXCK)1T c(A3)n SR XCK positive level pulse duration (except fornormal signal receiving)t w(RXDT)9T c(A3)n SR XDT- positive/negative level duration,definite (except for normal signal receiving)D imensional Outline Drawing - 16-pin SOP(Dimensions in mm)0 - 100.55~1.052.00(MAX)0.05(MIN)0.100.15(TYP)!Applied Circuit Configuration - ExampleS hown below is an example of applied circuit configuration for constructing a TIRIS Transmit-Receive RF-module using the RI-RFM-006A. This example illustrates a simplified amplifier circuit for received signals by eliminating a frequency band rejection filter which effectively eliminates external noises and signals out of the frequency band of the response signals from the remote TIRIS transponder. In this configuration, therefore, it is assumed that the available data communication distance of the system could be easily affected by environmental conditions.N ote that this is only one of various possible applications. For more information of applied circuit configurations, refer to the Application Handbook issued by our TIRIS Operation Dept.* When configuring an applied circuit, take the following into account:•Choose the capacity of a resonance capacitor for clock generator oscillator in accordance with the oscillator characteristics.•Define the frequency accuracy and variation of the clock generator oscillator by conversion based on the specifications for the TIRIS transponder to be used together so that it can be within the range of17.17248 MHz to 17.18272 MHz (standard frequency: 17.1776 MHz).•Select the values at resonance points around 134.2 kHz for L and C of the antenna circuit, respectively. (In the example illustrated above, the following combination is used: antenna: 48 µH;capacitor: 0.03 µF = 0.01 µF x 3 units)•It is desirable to use a MOSFET having a low on-state resistance for antenna driver!Typical Transmitter Circuit ConfigurationT his RF-module IC is provided with “TXHI” and “TXLO” terminals which can drive external MOSFETs for driving the LC serial resonance antenna circuit. This resonance antenna circuit is to send 134.2-kHz signals to the remote TIRIS transponder. Use these terminals as illustrated below.I n this circuit configuration, by selecting a value for R1 within a range of several hundred ohms and in accordance with the characteristics of MOSFETs (T1 and T2) and introducing the selected value, the through current which is consumed by the MOSFETs themselves during transmission can be reduced. If the value for R1 is too high, the on-state resistances of T1 and T2 become very high and they will have difficulty in driving the LC resonance circuit, leading to a possible reduction of available data communication distance. Therefore, it is recommended that the value for R1 be defined after careful evaluation of the characteristics of T1 and T2.L1 and C1 in the LC resonance circuit may be mutually exchanged in position without giving significant adverse effects to the operating performance of the circuit. However, the connection as is as illustrated above is most preferable since it reduces potential influence of high-voltage transmission signals produced at C1 on T1 and T2, thus a higher efficiency is gained.T hree simple CMOS inverter type amplifiers are integrated in this RF-module IC in order to amplify the FSK signals received from a remote TIRIS transponder up to a satisfactory logic level. The IC is designed so as to permit their amplification factor and frequency characteristics to be selected within a certain range by the use of appropriate external parts and/or circuits. A typical applied receiver circuit is illustrated below.I n general, the FSK signals sent from a remote TIRIS transponder are found within a band of 120 kHz to 140 kHz, mainly due to dispersion of workmanship during manufacture and ambient temperature fluctuation during transmitting operation. Therefore, by damping signals that fall out of the above band range as much as possible, noise suppression performance can be improved. In the illustrated circuit configuration, amplifier input coupling capacitors C2, C4 and C6 are used to reduce extremely low-frequency noise signals, and amplifier output load capacitors C1, C3 and C5 to reduce high-frequency noises. If you desire to enhance the noise resistance of the circuit still more, it is necessary to install a required number of external wide band amplifiers with high amplification factor and add an active band pass filter, LC resonance circuit, etc.D1, D2 and R4 for input into the first amplifier (A1) form a circuit to prevent high-voltage signals for power transmission and similar signals from entering the IC, thereby keeping from occurrence of latch-up or other adverse situations. This circuit or otherwise, an equivalent protector, must be inserted without fail.T he antenna circuit consisting of L and C illustrated earlier in this manual (see the section describing “Applied Circuit Configuration – Example”) is designed to work as an LC serial resonance circuit in which impedance drops in the presence of resonance frequencies during sending operation, and as an LC parallel resonance circuit in which impedance increases in the presence of resonance frequencies during receiving operation. The relationship between L and C incorporated in the resonance circuit can be defined according to the following expression. Each value is calculated using this expression:f LC()134.2KHz =12πT he higher the Q value (quality factor) is, the higher transmission power the antenna L obtains and also the higher the receiving gain becomes, thus allowing the system to have a greater available data communication distance. If, however, at switch-over from power transmission mode to the receiving mode, damping of the power transmission signal would not be completed before the remote TIRIS transponder sends its ID code back to the IC, the signals sent from the transponder could not be received properly. And the higher the Q value is, the longer the decay time of this power transmission signal will be. It has been revealed by experimental testing that an antenna with its maximum Q value of around 30 is usable in the circuit as is as illustrated in the “Applied Circuit Configuration – Example” section. If it is desired to use an antenna having a higher Q value, some measures must be devised and added to this circuit.A dditionally, the characteristics and efficiency of the resonance circuit used here greatly depend not only on the antenna L but also on the capacitor C and the MOSFETs which drive them. Therefore, the application of the lowest possible impedance at the frequency f(134.2 kHz) to them will permit a higher transmission power, and as a result, it will allow the system to have a greater available data communication distance with the remote transponder.!Precautions for Mounting and Actual UseDescribed in this section are the precautions to be taken at mounting and actual use of the RI-RFM-006A while designing and manufacturing a TIRIS Read-Write System using this IC, especially, critical issues as may affect the operating performance of the IC and, in particular, the system communication performance with a remote TIRIS transponder.1.Power Supply LineWhen the signals returned from a remote TIRIS transponder are amplified by sequentially using the three CMOS inverter type amplifiers incorporated in this RF-module IC, an undesirable feedback loop is formed from the third amplifier toward the first one through parasitic L, R and C whose formation is not avoidable because of the structure of this IC and its internal power supply line (see the diagram below) as CMOS devices are inevitably bi-directional. If this feedback loop is left as is, it normally leads to an oscillation; particularly, when the frequency band of each amplifier is limited so that it matches that of the transponder return signals, oscillation occurs at a frequency within this band which counts on high gains from the very nature of things, in consequence, adversely affecting the demodulating performance of the received FSK signals.Equivalent circuit for internal power supply line feedback loopThis situation does not a little occur when a multiple number of high-gain amplifiers are integrated in a CMOS device. Formation of this undesirable feedback loop in the amplifier band can be avoided by minimizing the impedance of the power supply line through optimization of the printed circuit boards and using a suitable bypass capacitor. It is extremely difficult to obtain true values for these parasitic L, R and C forming the internal power supply line feedback loop, but it can be said from the empirical viewpoint that it is possible to inhibit the said oscillation using a bypass capacitor with a capacity of 1 µF and having a sufficiently low impedance within the said amplifier frequency band provided that appropriate wiring patterns are defined for the power supply line on the printed circuit boards and in the peripheries of external parts for the amplifiers.Wiring for Antenna CircuitAs previously described, the FSK signals sent from a remote TIRIS transponder are normally found within a band of 120 kHz to 140 kHz. Therefore, the signal receiving circuit of this TIRIS Transmitter-Receiver System is designed so that the signal amplification factor is necessarily highest within this band. Because of this, all signals and noises which are produced by other devices and whose frequencies fall within this band greatly affect the system performance, especially, its available data communication distance with the remote TIRIS transponder among others.In the same way, they have quite the undesirable effect not only upon the environment in which the proper antenna for the system is found, but also upon the wire used to connect it with the IC’s “A1IN” pin which works as the first-phase amplifier for received signals. Furthermore, if there are wires for square or pulse wave logic signals containing high-frequency components (even though their fundamental frequencies are low) very close to this antenna connection wire, the system’s available data communication distance with the remote TIRIS transponder is further shortened due to the adverse effects of such wires. For all that, if there is no other alternative than to use a long wiring between the IC and its external antenna, it is suggested that a shielded wire be used for antenna wiring in either way as illustrated below. With this, the antenna wiring will be less susceptible to the aforementioned adverse effects.a. When the antenna is driven first.b. When the capacitor is driven first.。

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R epair instructions and/or specific problems relative to the product.MQS5056/1213e-mail:**************For latest product manuals:Shop online at ®User’s GuideServicing North America:U.S.A.:Omega Engineering, Inc., One Omega Drive, P.O. Box 4047S tamford, CT 06907-0047 USAToll-Free: 1-800-826-6342 (USA & Canada only)Customer Service: 1-800-622-2378 (USA & Canada only) Engineering Service: 1-800-872-9436 (USA & Canada only) Tel: (203) 359-1660 Fax: (203) 359-7700 e-mail:**************For Other Locations Visit /worldwide***********************The information contained in this document is believed to be correct, but OMEGA accepts no liability for any errors it contains, and reserves the right to alter specifications without notice.WARNING:These products are not designed for use in, and should not be used for, human applications.®Rev. 2013-12-16OM-ESW-105-POE Instruction SheetThis equipment is suitable for use in Class I, Division 2, Groups A, B, C and D or non-hazardous locations only.PACKAGE CONTENTS: One OM-ESW-105-POEUNPACKING: Remove all the equipment from the packaging, and store the packaging in a safe place. File any damage claims with the carrier.APPLYING POWER (Top View)Unscrew & Remove the DC Voltage Input Plug from the top header.Install the DC Power Cables into the Plug observing polarity as shown above. Plug the Voltage Input Plug back into the top header.Tightening torque for the terminal block power plug is (0.22 Nm) 2 lbs/in. Apply power.Note: It is only safe to turn the power on the wires after the wires have been secured to the OM-ESW-105-POE. WARNING: Inserting the input plug while the 48VDC is applied may cause arcing, and damage the input connector permanently.Verify the Power LED stays ON (GREEN).Note: Either V 1 or V 2 can be connected to power for minimal operation. For redundant power operation, V 1 and V 2 plugs must be connected to separate DC Voltage sources. Use wire sizes of 10-20 gauge. The power cord should be limited to less than 10 meters in order to ensure optimum performance. For OM-ESW-105-POE use 60/75°C rated copper wire.Note: Redundant power inputs will not balance the power loads. Only load from one power supply is used at a time. Note: The large #6 mounting/grounding screws located on the back plate must not be longer than 1/4". Recommended Power Supplies: DC 48V/5 AmpTo download the User Manual please visit the following location:/manuals/manualpdf/M5164.pdfLEDColorDescriptionGreen Valid Power (46-54 VDC) is applied.V1Red Invalid Power (<46 VDC) is applied or Power Bus Fault detected.OFF No Power is applied to the device. V2Green Valid Power (46-54 VDC) is applied.Red Invalid Power (<46 VDC) is applied or Power Bus Fault detected.OFF No Power is applied to the device. POE GreenPOE is being applied to the respective ports.Blinking POE PD detected with improper power classification.OFF No POE PD detected on the port.LNK ACTGreen Link with no or little activity. Blinking Link with activity. OFF No link established. SPD 100Green 100 Base OFF10 BaseWARNING ALERTE – Risque D’explosion – Remplacement d’un composant peut empêcher la conformité de Classe I, Division 2.ALERTE – Risque D’explosion – Ne débranchez pas tant que le circuit est sous tension sauf si la zone est connue pour être non dangereux.ALERTE – Risque D’explosion – Ne pas remplacer le dispositif que l’alimentation est coupée ou que la zone est connue pour être non dangereux.– Explosion Hazard – Substitution of any component may impair suitability for Class I, Division 2.WARNING – Explosion Hazard – Do not disconnect while circuit is live unless area is known to be non-hazardous.WARNING – Explosion Hazard – Do not replace the device unless power has been switched off or the area is known to be non-hazardous.。

VISIT ADRV9026Quad-Channel, Wideband RF Transceiver Platform200 MHz Bandwidth Integrated Radio Transceiver SolutionApplications►Macro base stations ►Massive MIMO►Small cell designs1See page 3 for future enhancements in the ADRV902x family roadmapSmallest Size, Lowest Power Transceiver Solution for Base Transceiver Stations (BTS )►Smallest size reduces footprint and enhances form factor flexibility►50% power consumption reduction over previous generation ADRV9009 for increased radio density►Enables ORAN small cell designs with lowest system power and costHighly Integrated, High Performance Software-Defined Radio►2× integration over ADRV9009►Supports up to 200 MHz bandwidth and covers all bands from 650 MHz to 6 GHz 1Common Platform Design for 3G/4G/5G Reduces Complexity, Development Costs, and Time to Market►Single-chip FDD/TDD solution simplifies hardware and software development ►Common API across multiple applications►Reduces product development cycles for band and power variants►Enables modular architecture for scalable radio solutionsADRV9026 Quad-Channel, Wideband RF Transceiver Platform RF SynthRF Synth ORX1/ORX2TX 1TX 2RX10°90°RX2RX3+RX3–RX4+RX4–RX1+RX1–RX2+RX2–TX3+TX3–TX4+TX4–TX1+TX1–TX2+TX2–ORX3+ORX3–ORX4+ORX4–ORX2+ORX2–ORX1+RF SynthLO 1LO 2GPIO AuxADC AuxDACGPINT1JESD204B/C Serial InterfaceClock GenerationandSynchronizationDEVCLK±SYSREF±LO 2LO 1LO 2LO 1RX3, RX4, TX3, TX4, ORX 3/ORX4RX1, RX2, TX1, TX2, ORX 1/ORX2pFIR,LO Leakage,QEC, Tuning,InterpolationGPIO_ANA_n AUXADC_nSPI_CLKSPI_EN SPI_DO SPI_DIORXn_EN TXn_EN ORXn_EN VDDA_1P8VDDA_1P3VDDA_1P0VDIG_1P0EXT_LO1±EXT_LO2±PWR MGMTGPINT2RESET TESTSERDOUTA±SYNCIN1±SYNCIN2±SYNCIN3±SERDINA±SERDINB±SERDINC±SERDIND±LO 3LO 3SYNCOUT1±SYNCOUT2±8419VIF444SERDOUTB±SERDOUTC±SERDOUTD±MicroprocessorADCADCDACDACADCADCDecimation,pFIR,DC Offset,QEC,Tuning,OverloadDecimation,pFIR, AGC,DC Offset,QECTuning RSSI,OverloadControl InterfaceSPI Port0°90°0°90°2ADRV9026 Quad-Channel, Wideband RF Transceiver Platform3Visit ADRV9026 Overview►Four differential transmitters ►Four differential receivers►Two observation receivers with two inputs each ►Center frequency: 650 MHz to 6000 MHz ►Maximum receiver bandwidth: 200 MHz ►Maximum transmitter bandwidth: 200 MHz►Maximum transmitter synthesis bandwidth: 450 MHz►Maximum observation receiver bandwidth: 450 MHz►Fully integrated independent fractional-N radio frequency synthesizers ►Fully integrated clock synthesizer►Multichip phase synchronization for all local oscillators and baseband clocks ►Support of TDD/FDD 3G/4G/5G applications►16 Gbps JESD204B/C digital interfaceSee roadmap below for future enhancementsADRV9026 Family RoadmapEnhanced features and functions will be added to the ADRV9026 over time, including:►25 Gbps SERDES support►Extending LO frequency range down to 75 MHz►Support for an external LO►Filter Wizard to generate custom profilesAn enhanced version from the ADRV902x family will be released in 2020 with integrated DPD and CFR, reducing FPGA requirements, as well as lowering total system power and cost.RadioVerse Ecosystem and PartnershipsRadioVerse ® is a design and technology ecosystem for advanced radio design and development. We offer market-leading integrated transceiver technology, software tools, evaluation and prototyping platforms, a range of reference designs, and radio solutions. RadioVerse is building up a global partnership network to provide customers all levels of design support. ADRV9026’s partner network and reference design ecosystem will be launched on /radioverse in 2020.Evaluation SystemThe evaluation system comprises an FPGA carrier board ADS9-V2EBZ and a radio daughtercard, coming with two frequency bands of matching: –HB for 2.8 GHz to 6 GHz and –MB for 650 MHz to 2.8 GHz. Compatible evaluation software is provided for download, including API library, Windows GUI, and a binary image for FPGA configuration.Radio CardsCarrier BoardsSoftware and DriverE v a l u a t i o n S y s t e m►ADRV902X-HB/PCBZ (for 2.8 GHz to 6 GHz )►ADRV902X-MB/PCBZ (for 650 MHz to 2.8 GHz )►ADS9-V2EBZ(FPGA motherboard with Xilinx ® UltraScale+™)►Operating system-agnostic API source in ANSI C►Windows GUI for transceiver configuration and data capture►Binary image for FPGA configurationFor regional headquarters, sales, and distributors orto contact customer service and technical support, visit /contact.Ask our ADI technology experts tough questions, browse FAQs, or join a conversation at the EngineerZone Online Support Community. Visit .©2019 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners.PH21775-11/19(A)VISIT 。

Tender textRF-EXPLORER/6RF spectrum analyser, 15-2,700 MHz, 4,850-6,100 MHz,in a compact aluminium housing with two antennas (SMA connection) for the different frequency ranges, including to prevent frequency collisions when setting up radio links in the frequency range mentioned above.• Real-time monitoring of the frequency range used with indication of frequency and level (dBm and dBµV)• Backlit high-contrast graphic display (128 x 64 pixels)• Automarker function and manual marker positioning for setting an individual carrier frequency• Special Wi-Fi analyser with display of 13 WLAN channels• Max hold function for a reliable detection of ultra-short RF carrier frequencies (additional modes: normal, max., average, overwrite)• Mini USB 2.0 interface for connection to a PC or laptop as well as for charging the built-in rechargeable lithium polymer battery (1,000 mAh)• Supplied with transport bag and USB cable• Client software with real-time analysis for Windows XP/Vista/Win7/Win8.x/Win10/Windows Server (32‑bit or 64‑bit version) can be downloaded at • Dimensions: 71 x 122 x 25 mm• Weight: 210 gSpecifications:Display graphic display (128 x 64 pixels)Frequency15-2,700 MHz,4,850-6,100 MHzAdmiss. ambient temp.0-40 °CDimensions71 x 122 x 25 mmWeight210 gPower supply rech. lithium polymer battery, 1000 mAhSpecial features mini USB portBrand: MONACORType: RF-EXPLORER/6Quantity: 1Packing dimensions (W x H x L): 0.12 x 0.05 x 0.17 mGross weight: 0.414 kgNet weight: 0.358 kgItem weight (w/o accessories): 0.21 kg。

MoMobula6 HDZERO 1s 65mm HD brushless whoopIntroducing Mobula6 HDZero, the very first 65mm HD brushless whoop in the World, weights less than 23.5 grams only!We have been working on innovations of Brushless Whoop for a few years. Just like many of you, we are particularly eager to have a 65mm FPV whoop carrying HD VTX. Teaming with HDZero, Runcam, Nick Burns, Mr Shutterbug, Ryan Quellet and many other enthusiasts, here the dream comes true finally!Specifications:Brand Name: HappymodelModel: Mobula6 HDZEROFrame wheelbase: 65mmWeight: 23.5 gram without batterySize: 80mm*80mm*50mmReceiver option:SPI ELRS 2.4GHzSPI FRSKY 2.4GHzCompatible with 1S Lipo battery or Lihv battery Battery Plug: PH2.0Package includes:Item NameMobula6 65mm frame+CanopySPI Receiver Option1: SuperbeeF4 Lite FC built-in ExpressLRS SPI RX SPI Receiver Option2: SuperbeeF4 Lite FC built-in Frsky SPI RXEX0802 KV19000 Unibell brushless motorGemfan 1210 31mm propeller(4cw+4ccw)HDZero Nano Lite CameraHDZero Whoop Lite VTXSpare CanopyPropeller disassemble toolScrew driverFlight controller SuperbeeF4 Lite ELRS/FRSKY SPI ELRS version Firmware target: CrazybeeF4SX1280SPI FRSKY version Firmware target: CrazybeeF4FRMCU:STM32F411CEU6 (100MHz, 512K FLASH)Sensor: MPU-6000 or ICM20689 or ICM42688P or BMI270(SPI connection)Power supply: 1S Lipo Lihv battery input (DC 2.8V~4.35V) Built-in 5A(each) Blheli_S 4in1 ESC Dshot600 readyBuilt-in Betaflight OSD(SPI Control)Built-in SPI Frsky/ExpressLRS receiverBuilt-in 5V 1A BECBuilt-in voltage detectionOnboard 4in1 ESC MCU upgraded to EFM8BB21Power supply: 1S LiPo/LiPo HV (2.8v~4.35v) Currents: 5A continuous peak 6A (5 seconds) Support BLHeliSuite programmableFactory firmware: S_H_50_REV16_8.HEX Default protocol: DSHOT150/DSHOT300/DSHOT600Onboard SPI ExpressLRS 2.4GHz Receiver Packet Rate option: 25Hz/50Hz/150Hz/250Hz/500Hz RF Frequency: 2.4GHzAntenna plug: IPEX Telemetry output Power: <12dBmReceiver protocol: SPI ExpressLRSCould bind with ELRS V2.0 firmware TX moduleOnboard Frsky SPI D8 /D16 2.4GHz Receiver SPI BUS receiver Frsky D8/D16 compatibleCompatible Non EU transmitter D8 model andEU-LBT(Frsky_x_lbt)Channels: 8ch or 16chFailsafe supportNo ground interference ( Transmitter and receiver 1 m from the ground): 100m~200mBased on CC2500 RF module Compatible with Futaba S-FHSS , Redpine protocolMotor Mode: EX0802 19000KVConfigu-ration:9N12PStator Diamter:8mmStator Length:2mmShaft Diameter:Φ1mmMotor Dimension(Dia.*Len):Φ10.5mm*14.9mm Weight(g):1.7gNo.of Cells(Lipo):1S onlyPropeller Gemfan 1219 Bi-blades Weight:0.19g Material: PC Pitch:1 inchProps Dia:30mmCenter Hole Dia:1mmHDZero Nano Lite Camera 14x16x11 mm1.5gram0.5 inch, up to 10650 mV/Lux-sec ultra-high sensitive CMos sensorExcellent low light performanceFov:4:3: D:130° H:108° v:84°16:9:D:122° H:108° V:65°HDZero Whoop Lite VTX 1S Input25mW/200mW RF Output-SmartAudio Support25.5×25.5 M2 Soft Mounting- Antenna Retention Removable Shielding Box- 32.5×32.5mm(29x29mm inner) 4.5grams/4mm Thickness (without shielding)Since different batches of flight controllers integrate different gyro sensor, please pay attention to the direction setting of the gyro sensorMPU6000/ICM20689/ICM42688P Gyro direction “CW90°”Yaw degrees “0”BMI270 Gyro direction “CW0°”Yaw degrees “0”。

专业术语常用名词缩写中英文对照(M-V)MAC:Medium Access Control Layer 介质访问控制层MBMC:Multiple Burst Mode Controller 多突发模式控制器MCF:Message Communication Function消息通信功能MD:Mediation Device中介设备MFPB:Multi-Frequency Press Button多频按键MIB:Management Information Base 管理信息库MIC：Mediu Interface Connector 介质接口连接器MIO:Multiuser Information Outlet 多用户信息插座MLM：Multi-Longitudinal Mode 多纵模MM:Mobile Management 移动管理MMDS:Maltichanned Microware Distribution System多路微波分配系统MMO:Multionedia Outlet 多媒体插座MN-NES:MN-Network Element System 网元管理系统MN-RMS:MN-Region Management System 网络管理系统MO:Managed Object 管理目标MSA:Multiplex Section Adaptation复用段适配MS-AIS:Mutiplex Section-Alarm Indication Signal 复用段告警指示信号MSOH:Multiplex Section Overhead 复用段开销MSP:Multiplex Section Protection复用段保护MS-RDI:Multiplex Section-Remote Defect Indication复用段远端缺陷指示MST:Multiplex Section Termination复用段终端MSU:Multi-Subscriber Unit 多用户单元MTIE:Maximum Time Interval Error最大时间间隔误差MUX:Multiplexer 灵活复接器NDF:New DataFlag 新数据标识NDFA:Niobium-Doped Fiber Amplifier 掺铌光纤放大器NE:Network Element 网元NEXT：Near End Crosstalk 近端串扰NMS:Network Management System网络管理系统NNE:Non-SDH Network Element 非SDH网元NNI:Network Node Interface网络节点接口NPI:Null Pointer Indication无效指针指示NWK:Network Layer 网络层NZ-DSF:Non Zero-Dispersion Shift Fiber 非零散位移光纤OAM&P:Operation Administration, Maintenance and Provisioning运行、管理、维护和预置OAM:Operation, Administration and Maintenance操作、管理和维护OBFD：Optical Beam Flame Detector 线型光速火焰探测器OC-N:Optical carrier level-N光载波级NOCR:Optical Character Recogmition光学字符识别OEIC:Optoelectronic Integrated Circuit光电集成电路OFA:Optical Fiber Amplifier 光纤放大器OHP:Overhead Processing开销处理OLT:Optical Line Terminal光纤线路终端ON:Orerall Noise 总噪声ONU:Optical Network Unit 光纤网络单元OOF:Out Of Frame 帧失步OOP:Object Oriental Programming面向对象程序设计OS:Operating System 操作系统OSC:Oscillator 振荡器OSI:Open Systems Interconnection开放系统互连OTDK：Optical Time Doman Reflectometer 光时域反射线OTDM:Optical Time Division Multiplexing 光时分复用PA:Power Amphfier 功率放大器PA:Power Amplifier 功率放大器PABX:Private Auntomatic Branch Exchange 程控数字自动交换机Paging :无线呼叫系统PAL:Pinhole Alc Lons 针孔型自动亮度控制镜头PARK:Portable Access Rights Key 移动用户接入权限识别码PAS:Public Address System 公共广播音响系统PBX:Private Brancn exchange 程控用户交换机PC:Pan unit&control 云台及云台控制器PC:Proximinty Card 接近卡PCM:Pulse Code Modulation 脉冲编码调制PCS:Personal Communication Service个人通讯服务PDFA:Praseodymium-Doped Fiber Amplifier 掺镨光纤放大器PDH:Plesiochronous digital Hierarchy 准同步数字系列PDN:Public data network 公用数据网PDS:Premises Distribution Systemn建筑物结构化综合布线系统PF:Pressurization Fan 加压风机PG:Pressure Gradient 压差式PID:Passire Infrared Detector 被动式红外传感器PJE:Pointer Justification Event 指针调整事件PLC:Programmerable Logic Controller 可编程控制器PM:Power Matching 功率匹配PMS:Prooerty Management system 资源管理系统PO:Pressure Operated 压强式POH:Path Overhead 通道开销PPI:PDH Physical InterfacePDH物理接口Preamplification :前置放大PRI:Primany Rate Interface 基群速率接口PRM:Patter Recogniton Method模式识别法PSC:Protection Switching Count 保护倒换计数PSD:Photoelectric Smoke Detector 光电感烟探测器PSD:Protection Switching Duration保护倒换持续时间PSK:Phase Shift Keying 移相键控PSNT：Ponver Sum Next 综合近端串扰PSPDN:Packet switched Public Data Network 公众分组交换网PSTN:Public Switch Telephone Network 公用交换电话网PU:Pick Up 拾音器PVC:Polyvingl chloride 聚氯乙烯PVCS:Public video conferring system 公用型会议电视系统PWS:Power system 电源系统ITU-T:International Telecommunication Union-Telecommunication Sector国际电信联盟-电信标准部R:Receiver 终端解码器R:Reverberator 混响器RC:Radio Communication移动通信RC:Room's Coefficient 房间系数RCU:Remote Control Units 终端控制器RDI:Remote Defect Indication 远端失效指示REG:Regenerator 再生器Resolution:清晰度RF:Radio Frequency 射频RHE:Romote Head End 远地前端RMC:Repeater Management Controller天线信道控制器RMS:Root Mean Square 均方根值RMU:Redundancy Memory Unit 冗佘存贮器RORTD:Rate Of Rise Thermal Detector 差温探测器RR:Reverberation Radius 混响半径RS:Reflected sound 反射场RSOH:Regenerator Section Ouerhead 再生段开销RSSI:Radio Signal Strength IndicatorRST:Regenerator Section Termination 再生段终端RSU:Remote Subscriber Unit 远端用户单元RT:Real Time 实时RT:Reverberation Time 混响时间RWS:Remote Workstation 远端工作站S:Sprinkler 分配器S:Stereo 双声道S:Strike 电子门锁SAA:Sound Absorption Ability 吸声能力SAR:Segmetation and reassembly sublayer 拆装子层SATV:Sate Llite 卫星电视SBS:Synchronous Backbone System 同步信息骨干系统SBSMN:SBS SBS Management Network 系列传输设备网管系统SC:Smart Card 智能卡SC:Subscriber Connector (Optial Fiber Connector)用户连接器（光纤连接器）SC:Supervisong Center 中央站监控中心管理中心SCADA:监控和数据采集软件SCB:System Control Board 系统控制板SCC:System Control&Communication系统通信控制SC-D:Saplex sc commector 双ISC连接器SCD:Sound Console Desk 调度台SCPC:Single Chnanel Per Carrier 卫星回程线路SCS:Stractured Cabling System 结构化布线系统SD:Signal Degraded 信号劣化SD:Smoke damper 排烟阀SD:Smoke Detector 感烟探测器SD:System Distortion 系统失真SDCA:Synchronization DCA同步数据通讯适配器SDMA:Spaee Division Multiplex Access容分SDXC:Synchronous Digital Cross Connect 同少数字交叉连接SE:Sound Energy 声能SEC:SDH Equipment Clock SDH 设备时钟SED:Sound Energy Density 声能密度SEEF:Smoke Extractor Exhaust Fan 排烟风机SEMF:Synchronous Equipment Management Function同步设备管理功能SES:Severely Errored Second 严重误码秒SESR:Severely Errlred Second Ratio严重误码秒比率SETPI:Synchronous Equipment Timing Physical Interface同步设备定时物理接口SETS:Synchronous Equipment Timing Source同步设备定时源SF:Spur Feeder 分支线SF:Subscribers Feeder 用户线SFN:Sound Field Nonunifornity 声场不均匀度SFP:Sound Field Processor 声场处进器SI:Sound Installation 音响设备SI:Sound Insulation隔音SICS:Simultaneous Interpretation Conference system同声传译系统SIPP:Service Interface and protocol processing unit业务接口和协议处理单元SLC:Sate llite Commumication 卫星通信SLI:Synchronous Line Optical Interface同步线路光口板SLIC:Subscriber Line Interface Controller用户线接口控制器SLM:Signal Label Mismatch 信号标记失配SM:Synchronous Multiplexer同步复用器SMF:System management function系统管理功能SMS:SDH Management Sub -Network SDH管理子网SNA:System Network Architecture 系统网络建筑SNI:Service Node Interface业务节点接口SNK:Sighal To Noise Ratio 信噪比SOA:Semiconductor Optical Amplifier半导体光放大器SOH:Section Overhead 段开销SONET:Synchronous Optical Network同步光网络SPF:Service Port Function业务口功能SPI:SDH Physical InterfaceSDH物理接口SPL:Sound Pressure Level 声压级SRL:Stractural Return Loss 结构器波损耗SS:Shock sensors 震动传感器SS:Sound Source 音源SS:Sprinkler System 自动喷水灭火系统SSB:Single Side Band 单边带调制SSM:Synchronous Status Message 同步状态信息SSU:Scan and Signal Unit 扫描及信号单元ST:Straight Tip 直通式光纤连接器ST:Subscribers Tap 用户分支器STB:Set -Top -Box 机项盒STC:Short -Term Card 计时票STE:Signaling Transfer Equipment 信令转换设备STG:Synchronous Timing Generator同步定时发生器STI:Surface fransfer Inpedane 表面传输阻扰STI:Surface Tranfer Inpedance 表面传输阻抗STM-N:Synchronous Transport Module level-N同步传送模块等级NSU:Subscriber Unit用户单元SV:Smoke Vent 排烟器SVCS:Sound Veinforcement System扩声系统T:Teletext 可视图文T:Terminal 终端机TA:Trunk Amplifier 干线放大器TC:Telecommunication Closet 通信插座TC:Transient Characteristic瞬间特性TCI:Trunk cabling interface 星形连接TCP/P:Transmission Control Protocol Inter-network Protocol传输控制协议/网间协议TCS:Tele Communication System 通信系统TCS:Telecommunication System 通讯系统TD:Ticket Dispemser 发卡机TDD:Time Division Dual 时分双工TDEV:Time Deviation时间偏差TDM:Time Division Multiplexing时分复用TDMA:Time Division Multiple Address时分多址TDS:Time division switching 时分交换结构TELEX:用户电报电传TEP:时间/事件软件TF:Transfer Function传送功能TFCC:Transmission frequenay Characteristic传输频率特性TGNP:The Greatest Noise Power 最大噪声功率TIM:Trace Identifier Mismatch追踪识别符失配TM:Termination Multiplexer 终端复用器TMN:Telecommunication Management Network 电信管理网TMN:Telecommunication Management Network电信管理网TNL:Total Noise Level 总噪声级TO:Telecommunications Outlet通信插座TP：Tunst Pair 对绞线TR:Token Ring 令牌网TSI:Timeslot Interxhange时隙交换TSU:Time Switching Unit 时隙交换单元TTF:Transport Terminal function 传送终端功能TTS:Tri Technology Sensor三鉴传感器TU:Tributary Unit 支路单元TUG:Tributary Unit Group 支路单元组TU-LOM:TU-Loss Of Multi-frame 支路单元复帧丢失TUP:Tributary Unit Pointer 支路单元指针TUPP:Tributary Unit Payload Process支路净荷处理UA T:Ultra Aperture Terminal 超小口径卫星地面接收站UL：Underwriters Laboratory 担保实验室UM:Unidirectional Microphines 单指向性传声器V A:Vacant auditoria 空场VCI:Virtual chammel identifier 虚信道标识VCS:vIdeo conferphone system 会议电视系统VI:Video interphone 可视对讲门铃Video switchers 图象切换控制器Videotext :可视图文VOD:Video on demand 视频点播VSA T:Very Small Aperture Terminal 甚小口径天线地球站。

特性控制阀，有基于传感器运行的流量控制, 2 通, 法兰, PN 16 (EPIV)• 额定电压 AC/DC 24 V• 控制方式 调节型, 交互通信式, 混合模式• 用于闭式的冷、热水系统• 用于供热通风系统中水侧的调节控制• 通过 BACnet MS/TP ，Modbus RTU ，Belimo-MP-Bus 通讯交互或常规控制• 有源传感器信号的转换和切换触点型号概述型号DNV'nom [l/s]V'nom [l/min]V'nom [m³/h]kvs theor. [m³/h]PN EP065F+MOD 65848028.85016EP080F+MOD 801166039.67516EP100F+MOD 1002012007212716EP125F+MOD 125311860111.619516EP150F+MOD15045270016225416理论kvs: 理论 kvs 值用于压降计算技术数据电气参数额定电压AC/DC 24 V 额定电压频率50/60 Hz额定电压范围AC 19.2...28.8 V / DC 21.6...28.8 V 运行功耗 6 W (DN 65, 80)9 W (DN 100, 125, 150)保持功耗 4.5 W (DN 65, 80)6 W (DN 100, 125, 150)变压器容量10 VA (DN 65, 80)12 VA (DN 100, 125, 150)连接方式电缆 1 m, 6 x 0.75 mm²数据总线通信通讯协议BACnet MS/TPModbus RTU (默认设置)MP-Bus节点数量BACnet / Modbus 详见接口描述MP-Bus 最多 8 个功能参数运行范围 Y 2...10 V 运行范围 Y 可调0.5...10 V 位置反馈信号U 2...10 V 位置反馈信号U 说明最大 1 mA 位置反馈信号U 可调起点 0.5...8 V 终点 2...10 V 电机噪音等级45 dB(A)可调节流量 V'max 30 ... 100％的Vnom控制精度±5% (V’nom 的25...100%)@20°C/ 不含乙二醇溶液控制精度注释±10% (V’nom 的25...100%)@-10...120°C/ 浓度为0...50%的乙二醇溶液最小可控流量V'nom 的 1%介质冷、热水，最大浓度50%的乙二醇溶液介质温度-10...120°C [14...248°F]关闭压力 ∆ps690 kPa••••运行方式功能参数压差 Δpmax 340kPa流量特性等百分比，在起始范围内优化 (可改为线性)泄漏率气密，泄漏等级A (EN12266-1)管道连接法兰连接，EN1092-2 (PN 16)安装位置向上垂直或水平安装 (参照阀轴)维护免维护手动操作按下手动操作钮，执行器齿轮机构解锁流量测量测量原理超声波流量测量流量测量精度±2% (V'nom 的25...100%) @ 20°C / 不含乙二醇流量测量精度注释±6% (V'nom 的25...100%) @ -10...120°C / 乙二醇浓度为0...50%最小流量测量单位V'nom 的 0.5%安全参数防触电保护等级IEC/EN III ，安全特低电压 (SELV)电气防护等级IEC/EN IP54压力设备指令CE 遵循 2014/68/EU EMC CE 遵循 2014/30/EU 运行方式类型 1额定冲击电压0.8 kV 污染等级3环境湿度最大 95% 相对湿度，无结露环境温度-30...50°C [-22...122°F]存储温度-20...80°C [-4...176°F]材质阀体EN-GJL-250 (GG 25)流量测量管段EN-GJL-250 (GG 25), 带防护漆阀芯不锈钢 AISI 316阀轴不锈钢 AISI 304阀轴密封EPDM阀座PTFE ，Viton O 形圈安全注意事项该设备是专为供热、通风及空调行业所设计。

常用测井曲线符号单位测井曲线名称符号(常用) 单位符号单位符号名称自然伽玛 GR API自然电位 SP MV 毫伏井径 CAL cm 厘米中子伽马 NGR冲洗带地层电阻率 Rxo深探测感应测井 Ild中探测感应测井 Ilm浅探测感应测井 Ils深双侧向电阻率测井 Rd浅双侧向电阻率测井 Rs微侧向电阻率测井 RMLL感应测井 CON声波时差 AC密度 DEN g/cm3中子 CN v/v孔隙度 POR冲洗带含水孔隙度 PORF渗透率 PERM 毫达西含水饱和度 SW冲洗带含水饱和度 SXO地层温度 TEMP有效孔隙度 POR泥浆滤液电阻率 Rmf地层水电阻率 Rw泥浆电阻率 Rm微梯度 ML1或MIN微电位 ML2或MNO补偿密度 RHOB或DEN G/CM3补偿中子 CNL或NPHI声波时差 DT或AC US/M 微秒/米深侧向电阻率 LLD或RT OMM 欧姆米浅双侧向电阻率 LLS或RS OMM 欧姆米微球电阻率 MSFL或SFLU、RFOC中感应电阻率 ILM或RILM深感应电阻率 ILD或RILD感应电导率 CILD MMO 毫姆欧PERM绝对渗透率，PIH油气有效渗透率，PIW水的有效渗透率。

测井符号英文名称中文名称Rt true formation resistivity. 地层真电阻率Rxo flushed zone formation resistivity 冲洗带地层电阻率Ild deep investigate induction log 深探测感应测井Ilm medium investigate induction log 中探测感应测井Ils shallow investigate induction log 浅探测感应测井Rd deep investigate double lateral resistivity log 深双侧向电阻率测井Rs shallow investigate double lateral resistivity log 浅双侧向电阻率测井RMLL micro lateral resistivity log 微侧向电阻率测井CON induction log 感应测井AC acoustic 声波时差DEN density 密度CN neutron 中子GR natural gamma ray 自然伽马SP spontaneous potential 自然电位CAL borehole diameter 井径K potassium 钾TH thorium 钍U uranium 铀KTH gamma ray without uranium 无铀伽马NGR neutron gamma ray 中子伽马5700系列的测井项目及曲线名称Star Imager 微电阻率扫描成像CBIL 井周声波成像MAC 多极阵列声波成像MRIL 核磁共振成像TBRT 薄层电阻率DAC 阵列声波DVRT 数字垂直测井HDIP 六臂倾角MPHI 核磁共振有效孔隙度MBVM 可动流体体积MBVI 束缚流体体积MPERM 核磁共振渗透率Echoes 标准回波数据T2 Dist T2分布数据TPOR 总孔隙度BHTA 声波幅度BHTT 声波返回时间Image DIP 图像的倾角COMP AMP 纵波幅度Shear AMP 横波幅度COMP ATTN 纵波衰减Shear ATTN 横波衰减RADOUTR 井眼的椭圆度Dev 井斜原始测井曲线代码AMP5 第五扇区的声幅值AMP6 第六扇区的声幅值AMVG 平均声幅AO10 阵列感应电阻率AO20 阵列感应电阻率AO30 阵列感应电阻率AO60 阵列感应电阻率AO90 阵列感应电阻率AOFF 截止值AORT 阵列感应电阻率AORX 阵列感应电阻率APLC 补偿中子AR10 方位电阻率AR11 方位电阻率AR12 方位电阻率ARO1 方位电阻率ARO2 方位电阻率ARO3 方位电阻率ARO4 方位电阻率ARO5 方位电阻率ARO6 方位电阻率ARO7 方位电阻率ARO8 方位电阻率ARO9 方位电阻率AT10 阵列感应电阻率AT20 阵列感应电阻率AT30 阵列感应电阻率AT60 阵列感应电阻率AT90 阵列感应电阻率ATAV 平均衰减率ATC1 声波衰减率ATC2 声波衰减率ATC3 声波衰减率ATC4 声波衰减率ATC5 声波衰减率ATC6 声波衰减率ATMN 最小衰减率ATRT 阵列感应电阻率ATRX 阵列感应电阻率AZ 1号极板方位AZ1 1号极板方位AZI 1号极板方位AZIM 井斜方位BGF 远探头背景计数率BGN 近探头背景计数率BHTA 声波传播时间数据BHTT 声波幅度数据BLKC 块数BS 钻头直径BTNS 极板原始数据C1 井径C2 井径C3 井径CAL 井径CAL1 井径CAL2 井径CALI 井径CALS 井径CASI 钙硅比CBL 声波幅度CCL 磁性定位CEMC 水泥图CGR 自然伽马CI 总能谱比CMFF 核磁共振自由流体体积CMRP 核磁共振有效孔隙度CN 补偿中子CNL 补偿中子CO 碳氧比CON1 感应电导率COND 感应电导率CORR 密度校正值D2EC 200兆赫兹介电常数D4EC 47兆赫兹介电常数DAZ 井斜方位DCNT 数据计数DEN 补偿密度DEN_1 岩性密度DTST 斯通利波时差ECHO 回波串ECHOQM 回波串ETIMD 时间FAMP 泥浆幅度FAR 远探头地层计数率FCC 地层校正FDBI 泥浆探测器增益FDEN 流体密度FGAT 泥浆探测器门限FLOW 流量FPLC 补偿中子FTIM 泥浆传播时间GAZF Z轴加速度数据GG01 屏蔽增益GG02 屏蔽增益GG03 屏蔽增益GG04 屏蔽增益GG05 屏蔽增益GG06 屏蔽增益GR 自然伽马GR2 同位素示踪伽马HAZI 井斜方位HDRS 深感应电阻率HFK 钾HMRS 中感应电阻率HSGR 无铀伽马HTHO 钍HUD 持水率HURA 铀IDPH 深感应电阻率IMPH 中感应电阻率K 钾KCMR 核磁共振渗透率KTH 无铀伽马LCAL 井径LDL 岩性密度LLD 深侧向电阻率LLD3 深三侧向电阻率LLD7 深七侧向电阻率LLHR 高分辨率侧向电阻率LLS 浅侧向电阻率LLS3 浅三侧向电阻率LLS7 浅七侧向电阻率M1R10 高分辨率阵列感应电阻率M1R120 高分辨率阵列感应电阻率M1R20 高分辨率阵列感应电阻率M1R30 高分辨率阵列感应电阻率M1R60 高分辨率阵列感应电阻率M1R90 高分辨率阵列感应电阻率M2R10 高分辨率阵列感应电阻率M2R120 高分辨率阵列感应电阻率M2R20 高分辨率阵列感应电阻率M2R30 高分辨率阵列感应电阻率M2R60 高分辨率阵列感应电阻率M2R90 高分辨率阵列感应电阻率M4R10 高分辨率阵列感应电阻率M4R120 高分辨率阵列感应电阻率M4R20 高分辨率阵列感应电阻率M4R30 高分辨率阵列感应电阻率M4R60 高分辨率阵列感应电阻率M4R90 高分辨率阵列感应电阻率MBVI 核磁共振束缚流体体积MBVM 核磁共振自由流体体积MCBW 核磁共振粘土束缚水ML1 微电位电阻率ML2 微梯度电阻率MPHE 核磁共振有效孔隙度MPHS 核磁共振总孔隙度MPRM 核磁共振渗透率MSFL 微球型聚焦电阻率NCNT 磁北极计数NEAR 近探头地层计数率NGR 中子伽马NPHI 补偿中子P01 第1组分孔隙度P02 第2组分孔隙度P03 第3组分孔隙度PD6G 屏蔽电压PE 光电吸收截面指数PEF 光电吸收截面指数PEFL 光电吸收截面指数PERM-IND 核磁共振渗透率POTA 钾PPOR 核磁T2谱PPORB 核磁T2谱PPORC 核磁T2谱PR 泊松比PRESSURE 压力QA 加速计质量QB 磁力计质量QRTT 反射波采集质量R04 0.4米电位电阻率R045 0.45米电位电阻率R05 0.5米电位电阻率R1 1米底部梯度电阻率R25 2.5米底部梯度电阻率R4 4米底部梯度电阻率R4AT 200兆赫兹幅度比R4AT_1 47兆赫兹幅度比R4SL 200兆赫兹电阻率R4SL_1 47兆赫兹电阻率R6 6米底部梯度电阻率R8 8米底部梯度电阻率RAD1 井径（极板半径）RAD2 井径（极板半径）RAD3 井径（极板半径）RAD4 井径（极板半径）RAD5 井径（极板半径）RAD6 井径（极板半径）RADS 井径（极板半径）RATI 地层比值RB 相对方位RB_1 相对方位角RBOF 相对方位RD 深侧向电阻率RFOC 八侧向电阻率RHOB 岩性密度RHOM 岩性密度RILD 深感应电阻率RILM 中感应电阻率RLML 微梯度电阻率RM 钻井液电阻率RMLL 微侧向电阻率RMSF 微球型聚焦电阻率RNML 微电位电阻率ROT 相对方位RPRX 邻近侧向电阻率RS 浅侧向电阻率SDBI 特征值增益SFL 球型聚焦电阻率SFLU 球型聚焦电阻率SGAT 采样时间SGR 无铀伽马SICA 硅钙比SIG 井周成像特征值SIGC 俘获截面SIGC2 示踪俘获截面SMOD 横波模量SNL 井壁中子SNUM 特征值数量SP 自然电位SPER 特征值周期T2 核磁T2谱T2-BIN-A 核磁共振区间孔隙度T2-BIN-B 核磁共振区间孔隙度T2-BIN-PR 核磁共振区间孔隙度T2GM T2分布对数平均值T2LM T2分布对数平均值TEMP 井温TH 钍THOR 钍TKRA 钍钾比TPOR 核磁共振总孔隙度TRIG 模式标志TS 横波时差PORH 油气重量NEWSANDBULK 出砂指数NEWSANDPERM 渗透率NEWSANDSW 含水饱和度NEWSANDSH 泥质含量NEWSANDCALO 井径差值NEWSANDCL 粘土含量NEWSANDDHY 残余烃密度NEWSANDSXO 冲洗带含水饱和度NEWSANDDA 第一判别向量的判别函数NEWSANDDB 第二判别向量的判别函数NEWSAND DAB 综合判别函数NEWSANDCI 煤层标志NEWSANDCARB 煤的含量NEWSANDTEMP 地层温度NEWSANDQ 评价泥质砂岩油气层产能的参数NEWSAND PI 评价泥质砂岩油气层产能的参数NEWSANDSH 泥质体积CLASSSW 总含水饱和度CLASSPOR 有效孔隙度CLASSPORG 气指数CLASSCHR 阳离子交换能力与含氢量的比值CLASS CL 粘土体积CLASSPORW 含水孔隙度CLASSPORF 冲洗带饱含泥浆孔隙度CLASSCALC 井径差值CLASSDHYC 烃密度CLASSPERM 绝对渗透率CLASSPIH 油气有效渗透率CLASSPIW 水的有效渗透率CLASSCLD 分散粘土体积CLASSCLL 层状粘土体积CLASSCLS 结构粘土体积CLASSEPOR 有效孔隙度CLASSESW 有效含水饱和度CLASSTPI 钍钾乘积指数CLASSPOTV １００％粘土中钾的体积CLASS CEC 阳离子交换能力CLASSQV 阳离子交换容量CLASSBW 粘土中的束缚水含量CLASSEPRW 含水有效孔隙度CLASSUPOR 总孔隙度，UPOR=EPOR+BW CLASS HI 干粘土骨架的含氢指数CLASSBWCL 粘土束缚水含量CLASSTMON 蒙脱石含量CLASSTILL 伊利石含量CLASSTCHK 绿泥石和高岭石含量CLASSVSH 泥质体积CLASSVSW 总含水饱和度CLASSVPOR 有效孔隙度CLASSVPOG 气指数CLASSVCHR 阳离子交换能力与含氢量的比值CLASS VCL 粘土体积CLASSVPOW 含水孔隙度CLASSVPOF 冲洗带饱含泥浆孔隙度CLASSVCAC 井径差值CLASSVDHY 烃密度CLASSVPEM 绝对渗透率CLASSVPIH 油气有效渗透率CLASSVPIW 水的有效渗透率CLASSVCLD 分散粘土体积CLASSVCLL 层状粘土体积CLASSVCLS 结构粘土体积CLASSVEPO 有效孔隙度CLASSVESW 有效含水饱和度CLASSVTPI 钍钾乘积指数CLASSVPOV １００％粘土中钾的体积CLASS VCEC 阳离子交换能力CLASSVQV 阳离子交换容量CLASSVBW 粘土中的束缚水含量CLASSVEPR 含水有效孔隙度CLASSVUPO 总孔隙度CLASSVHI 干粘土骨架的含氢指数CLASSVBWC 粘土束缚水含量CLASS VTMO 蒙脱石含量CLASSVTIL 伊利石含量CLASSVTCH 绿泥石和高岭石含量CLASS QW井筒水流量PLIQT井筒总流量PLISK射孔井段PLIPQW单层产水量PLIPQT单层产液量PLIWEQ 相对吸水量ZRPMPEQ 相对吸水强度ZRPMPOR 孔隙度PRCOPORW 含水孔隙度PRCOPORF 冲洗带含水孔隙度PRCO PORT 总孔隙度PRCOPORX 流体孔隙度PRCOPORH 油气重量PRCOBULK 出砂指数PRCOHF 累计烃米数PRCOPF 累计孔隙米数PRCOPERM 渗透率PRCOSW 含水饱和度PRCOSH 泥质含量PRCOCALO 井径差值PRCOCL 粘土含量PRCODHY 残余烃密度PRCOSXO 冲洗带含水饱和度PRCO SWIR 束缚水饱和度PRCOPERW 水的有效渗透率PRCOPERO 油的有效渗透率PRCOKRW 水的相对渗透率PRCOKRO 油的相对渗透率PRCOFW 产水率PRCOSHSI 泥质与粉砂含量PRCOSXOF 199＊SXO PRCOSWCO 含水饱和度PRCOWCI 产水率PRCOWOR 水油比PRCOCCCO 经过PORT校正后的C／O值PRCO CCSC 经过PORT校正后的SI／CA值PRCO CCCS 经过PORT校正后的CA／SI值PRCO DCO 油水层C／O差值PRCOXIWA 水线视截距PRCOCOWA 视水线值PRCOCONM 视油线值PRC。

Technical SpecificationSpecificationsRF UpstreamFrequency Range (MHz)5 to 85 (5 to 65 with Software Release 1.0)ModulationQPSK, 8 QAM, 16 QAM, 32 QAM, 64 QAM (No 8 QAM Support in Software Release 1.0)Channel TypeTDMA, ATDMA, TDMA/ATDMA, SCDMA (No SCDMA Support in Software Release 1.0)Data Rate (Mbps) (Max.)30.72 per channel RF Input Level (dBmV)-16 to +29Frequency Resolution (KHz)< 1Symbol Rate (Ksym/sec)160, 320, 640, 1280, 2560, 5120Bandwidth per Channel (MHz)0.2, 0.4, 0.8, 1.6, 3.2, 6.4PhysicalPower-48 V DC (-40 to -72 V DC )Power Consumption170 W nominal and TBD W max at -48 V DC , 77°F (25°C)Operating Temperature :Short Term °F (°C)+23 to +131 (-5 to +55)Long Term °F (°C)+41 to +104 (+5 to +40)Storage Temperature °F (°C)-40 to +158 (-40 to +70)Operating Humidity (Min.-Max.)5 to 85% (Non condensing)Dimensions (H x W x D) in. (cm)13.8 x 1.2 x 17. 8 (35.0 x 3.0 x 45.3) Weight lbs. (kg)approx. 4.6 (2.1)Support with Software Release 1.0 (Partial Feature List)Upstream CAM Flexible Mapping of Upstream Channels to RF Connectors Up to 12 Upstream Channels per RF Connector 24 RF (MCX) Connectors per Physical Interface Card (PIC)Up to 5+1 RF Sparing BPI/BPI+ Support DOCSIS ®3.0 Multicast IP Video Support via IGMPv3 Control IPv6 Features Cable modem management Dual-Stack CPE IS-IS Routing with Multi-topology support Cable Source Verify with DHCP Lease Query Route Injection (RI) for DHCPv6 Prefix Delegation OSPFv3Prefix Stability Distribute Lists TFTP Enforce / Dynamic Shared Secret DS and US Subscriber Management FiltersPolicy-Based RoutingDOCSIS 3.0 24 Channel Bonding (Downstream)DOCSIS 3.0 Four Channel Bonding (Upstream)IS-IS, BGPv4PacketCable™ Multimedia SupportDynamic Cable Modem Load BalancingSII Lawful Intercept (RFC 3924)802.1Q VLAN taggingExtended ACLs & Named ACLsSecure Shell v2 (SSHv2)DOCSIS PingDHCP Relay Agent (Option 82)DNS ClientTFTP Enforce and Dynamic Shared SecretBSoD L2 VPNBPI+ EnforceIPDR/SPContinued on the next page…E6000™Converged Edge Router (CER)Upstream Cable Access Module (UCAM) Technical SpecificationsARRIS Technical SpecificationsOrdering InformationPart Number DescriptionUCAM Kits799008E6000 CER 48 US UCAM Kit (Active) -1 UCAM, Active UCAM PIC, and 48 DOCSIS US Licenses801026E6000 CER 48 US UCAM Kit (Spare) -1 UCAM, Spare UCAM PIC, and 48 DOCSIS US Licenses802221E6000 CER 96 US UCAM Kit (Active) -1 UCAM, Active UCAM PIC, and 96 DOCSIS US Licenses802222E6000 CER 96 US UCAM Kit (Spare) -1 UCAM, Spare UCAM PIC, and 96 DOCSIS US LicensesLicense Bundles801062E6000 CER 48 DOCSIS US License BundleMaintenance Plan (required)801169E6000 Software Maintenance –Phone Plus GoldSpecifications are subject to change without notice.The capabilities, system requirements and/or compatibility with third-party products described herein are subject to change without notice. ARRIS, the ARRIS logo,Auspice®, BigBand Networks®, BigBand Networks and Design®, BME®, BME 50®, BMR®, BMR100®, BMR1200®, C3™, C4®, C4c™, C-COR®, CHP Max5000®,ConvergeMedia™, Cornerstone®, CORWave™, CXM™, D5®, Digicon®, E6000™, ENCORE®, EventAssure™, Flex Max®, FTTMax™, HEMi®, MONARCH®, MOXI®, n5®,nABLE®, nVision®, OpsLogic®, OpsLogic® Service Visibility Portal™, Opti Max™, PLEXiS®, PowerSense™, QUARTET®, Rateshaping®, Regal®, ServAssure™, ServiceVisibility Portal™, TeleWire Supply®, TLX®, Touchstone®, Trans Max™, VIPr™, VSM™, and WorkAssure™ are all trademarks of ARRIS Group, Inc. Other trademarks andtrade names may be used in this document to refer to either the entities claiming the marks and the names of their products. ARRIS disclaims proprietary interest inthe marks and names of others. © Copyright 2013 ARRIS Group, Inc. All rights reserved. Reproduction in any manner whatsoever without the express writtenpermission of ARRIS Group, Inc. is strictly forbidden. For more information, contact E6000UCAM_TS_20FEB13。

The PST-6IntroductionThank you for purchasing the Furman Power Station-6 Power Conditioner. For over 30 years, Furman has pioneered the development of AC power products for the most demanding audio, video, and broadcast professionals. Furman’s Ground Contamination Free Surge Protection, Advanced Filtering Technology, and Digital-HD Television Ready circuitry can signifi cantly improve your sensitive components while protecting them from spikes, surges and contaminated AC power.Today’s power grid typically experiences numerous electrical surges and spikes on a daily basis. At best, these irregularities can degrade your equipment’s performance; at worst, they can severely damage individual components or your entire system. Not so with Furman.With our exclusive Ground Contamination Free Surge Protection, your valued equipment is protected without the long-term damaging effect of conventional surge strips.Safety InformationTo obtain best results from your Furman Power Station-6 Power Conditioner, please be sure to read this manual carefully before using.Warning:To reduce the risk of electrical shock, do not expose this equipment to rain or moisture. Dangerous high voltages are present inside the enclosure. Do not remove the covers. There are no user serviceable parts inside. Refer servicing to qualifi ed personnel only.2Important Safety Instructions:1. Please read and observe all safety and operating instructions before installing your Power Station-6 (PST-6). Retain these instructions for future reference.2. Your PST-6 should not be used near water – for example, neara bathtub, washbowl, kitchen sink, laundry tub, in a wet basement, near a swimming pool, etc.3. Do not place your PST-6 near heat sources such as radiators, heat registers, stoves or other appliances that produce heat.4. The PST-6 should only be connected to a 120 VAC, 60Hz, 15 amp grounded electrical outlet. Do not defeat the ground or change polarization of the power plug.5. Route the power cord and other cables so that they are not likely to be walked on, tripped over, or stressed. Pay particular attention to the condition of the cords and cables at the plugs, and the point where they exit your PST-6. To prevent risk of fi re or injury, damaged cords and cables should be replaced immediately.6. Clean your PST-6 with a damp cloth only. Do not use solvents or abrasive cleaners. Never pour liquid on or into the unit.7. Your PST-6 should be serviced by qualifi ed service personnel when:3• The power supply cord or the plug has been frayed, kinked, or cut.• Objects have fallen or liquid has spilled into the unit.• The unit has been exposed to rain or other moisture.• The unit does not appear to operate normally, exhibits a marked change in performance, or the Protection OK indicator is not lit.• The unit has been dropped, or the enclosure damaged.8. Your PST-6 requires that a safety ground be present for properoperation. Any attempt to operate the unit without a safety ground is considered improper operation and could invalidate the warranty.OperationAC, Telephone, and Coaxial ConnectorsTelco – Satellite / Cable Transient Voltage Surge Suppressors: The PST-6 features transient voltage surge suppression for both standard telephone lines, as well as cable and satellite lines utilizing standard coaxial connectors. As these surge suppressors are in-line, they will require an additional cable (supplied with the PST-6) to connect from their output to the control device requiring protection.All in-line surge suppressors feature our exclusive ground contamination free technology. This aids in eliminating audio buzzing, and the video hum-bars that can result from typical in-line suppressors. Further, our cable and satellite suppressors are TIVO friendly as well as HD-Digital Television ready. Both DC carrier signals as well as high bandwidth signals can pass through our 4circuit. In fact the bandwidth is less than 0.1dB loss at 1GHz!To connect your cabling to these in-line protectors, simply follow thein and out indications marked next to the Telco, and Cable / Satellite connectors.Note:It is not possible to make an in-line cable / satellite protector “maintenance-free.” Under extreme conditions, it is possible that the surge suppression in one of these devices could sacrifi ce itself after a catastrophic event. If the telephone, cable or satellite signal will no longer pass through our protector, please send your Power Station to Furman for servicing. To test this, simply disconnect the incoming and out going cable from the PST-6. Connect the incoming connector to the component that formerly received the out going connector, thus by-passing the in-line protection. If the signalis present (but not when used with the PST-6) then the protection circuit is damaged (assuming it worked properly before the storm or catastrophic event).Circuit BreakerIf the PST-6 is connected to an AC outlet where suffi cient voltageis present, the unit should operate properly with the protection OK indicator lit, after the main power switch is turned to the on position.If the unit still does not function under these conditions check the circuit breaker button! It is the round black button adjacent to the incoming AC cord. If the circuit breaker trips immediately, there may be too great of a current load placed upon it. Simply disconnect one5product at a time until this no longer happens. If the breaker trips with no components connected, there may be a wiring defect that requires Furman service.IndicatorsProtection OK Indicator:Although Furman’s Ground Contamination Free Surge Suppression rarely requires servicing, nature has a way of occasionally creating electrical forces that are beyond the capabilities of any transient voltage surge suppressor device to absorb without some degree of damage. In the instance that this occurs, the blue “Protection OK” LED indicator will turn off. If this happens, Furman’s surge suppression circuit is compromised. The unit must be returned to Furman Sound, or an authorized Furman Service Center for repair.MountingIf the Power Station needs to be mounted to the inside panel of a rack or hung from a wall, a convenient crossed oval cutout is provided on the unit’s bottom panel. A standard No. 6 pan head screw can be used in the same way a picture is hung from a wall. Simply measure the centers on the bottom of your Power Station. This will be the distance from the two mounting holes drilled into your wall, rack or cabinet surface. Once the screw is fastened fl ush with the surface, back it out approximately ½”. The screw head should push through the crossed cutout on the bottom surface of the Power Station. Next, simply allow the Power Station to move down and seat into the end of its oval cut-out. Adjust the pan head screw if necessary.6WarrantyFurman Sound, Inc., having its principal place of business at 1997 South McDowell Blvd., Petaluma, CA 94954 (“Manufacturer”) warrants its PST-6 (the “Product”) as follows:Manufacturer warrants to the original Purchaser of the Product that the Product sold hereunder will be free from defects in material and workmanship for a period of one year from the date of purchase. The Purchaser of the product is allowed fi fteen days from the date of purchase to complete warranty registration by mail or on-line at the Furman website. If the Product does not conform to this Limited Warranty during the warranty period (as herein above specifi ed), Purchaser shall notify Manufacturer in writing of the claimed defects. If the defects are of such type and nature as to be covered by this warranty, Manufacturer shall authorize Purchaser to return the Product to the Furman factory or to an authorized Furman repair location. Warranty claims should be accompanied by a copy of the original purchase invoice showing the purchase date; this is not necessary if the Warranty Registration was completed either via the mailed in warranty card or on-line website registration. Shipping charges to the Furman factory or to an authorized repair location must be prepaid by the Purchaser of the product. Manufacturer shall, at its own expense, furnish a replacement Product or,at Manufacturer’s option, repair the defective Product. Return shipping charges back to Purchaser will be paid by Manufacturer.THE FOREGOING IS IN LIEU OF ALL OTHER WARRANTIES, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS7FOR A PARTICULAR PURPOSE. Manufacturer does not warrant against damages or defects arising out of improper or abnormal use of handling of the Product; against defects or damages arising from improper installation, against defects in products or components not manufactured by Manufacturer, or against damages resulting from such non-Manufacturer made products or components. This warranty shall be cancelable by Manufacturer at its sole discretion if the product is modifi ed in any way without written authorization from Furman Sound.This warranty also does not apply to Products upon which repairs have been affected or attempted by persons other than pursuant to written authorization by Manufacturer.THIS WARRANTY IS EXCLUSIVE. The sole and exclusive obligation of Manufacturer shall be to repair or replace the defective Product in the manner and for the period provided above. Manufacturer shall not have any other obligation with respect to the Products or any part thereof, whether based on contract, tort, strict liability or otherwise.Under no circumstances, whether based on this Limited Warranty or otherwise, shall Manufacturer be liable for incidental, special, or consequential damages. Manufacturer’s employees or representatives’ ORAL OR OTHER WRITTEN STATEMENTS DO NOT CONSTITUTE WARRANTIES, shall not be relied upon by Purchaser, and are not a part of the contract for sale or this limited warranty. This Limited Warranty states the entire obligation of Manufacturer with respect to the Product.If any part of this Limited Warranty is determined to be void or illegal, the remainder shall remain in full force and effect.8ServiceAll equipment being returned for repair must have a Return Authorization (R/A) Number. To get an R/A number, please call the Furman Service Department at (707) 763-1010 ext 121, between the hours of 8:00 am and 5:00 pm US Pacifi c Time. When returning equipment for repair, please use the original packaging to ship the product. Also, please enclose a note giving your name, address, phone number, e-mail address, and a description of the problem. Please display your R/A Number prominently on the front of all packages.91011Furman Sound, Inc.1997 South McDowell Blvd.Petaluma, California 94954-6919 USAPhone: 707-763-1010Fax: 707-763-1310Web: E-mail:********************12011104-D。

Wireless Thermocouple Temperature Data LoggerOM-CP-RFTCTemp2000AProduct OverviewThe OM-CP-RFTCTemp2000A is a wireless thermocouple based temperature monitoring and alarming system with LCD. A docking base is included with the data logger for mounting purposes.Selection ButtonsThe logger is designed with 3 direct selection buttons: Scroll, Units and Wireless.- Scroll: Allows user to scroll through information displayed on the LCD Screen.- Units: Allows user to change displayed units of measure to either °F or °C.- Wireless: Push and hold this button for 5 seconds to activate wireless communication.LED IndicatorsStatus: Green LED blinks every 5 seconds to indicate unit is logging.Wireless: Blue LED blinks every 40 seconds to indicate unit is operating in wireless mode.Alarm: Red LED blinks every 1 second to indicate an alarm condition.Remote Thermocouple ChannelA female subminiature (SMP) or pluggable screw terminal is located on the bottom of the logger to connect a thermocouple. The OM-CP-RFTCTemp2000A will accept thermocouple types J, K, T, E, R, S, B, or N.Wiring the ThermocoupleFor MP Model:Install the Omega data logging Software and USB Drivers onto a PC.Plug an OM-CP-RFC1000-EXT (sold separately) into a USB port on the base station computer.(For transmissions over distances longer than 500’ indoors line of sight (2,000’ outdoors), plug additional OM-CP-RFC1000-EXTs into electrical outlets in between the base station computer and the OM-CP-RFTCTemp2000A.) The red LED will illuminate on the OM-CP-RFC1000-EXT to signify that it has been connected correctly.Push and hold the wireless button on the OM-CP-RFTCTemp2000A for 5 seconds to activate wireless communication. The display will confirm “Wireless: ON” and the blue LED will blink every 40 unch the Omega data logging Software, the OM-CP-RFTCTemp2000A icon will automaticallyappear in the connected devices list, showing that the device has been recognized. Select the logger in the connected devices list, and click the “claim” button, wait for the device to finish updating. Select the Realtime Start method from the device tab and choose a desired reading rate from the drop-down menu and click “start”.To set up or choose an Alarm for a Realtime Session, select the alarm rules tab (Refer to the Alarm Settings section).Install the Omega data logging Software and USB Drivers onto a PC.Plug the USB to Mini USB cable (included with your logger) into a USB port on your computer. With the wireless mode turned “OFF” on your device, plug the opposite end of the cable into the communication port on your OM-CP-RFTCTemp2000A.Launch the Omega data logging Software, the OM-CP-RFTCTemp2000A icon will automatically appear in the software showing that the device is recognized. Select the logger in the software and choose your desired start method.To download your data, select the device, click the stop button, and then click the download button to view your report in the graph.1.2.3.4.Quick Start Steps1.2.3.4.Questions? For more details and instructions, please refer to the rest of this guide, visit us online at or contact us for support at 1 (800) 872-9436.Quick Start ManualOM-CP-RFTCTemp2000AAdditional Features and OperationAlarm Settings/Rules1. To create an alarm rule, select Manage Rules in the device tab of the software.2. Select New and enter a Rule name. Enter alarm the parameters using the drop down menus andselection circles.3. Select OK and choose the alarm to enable. The alarm bell is green when enabled and red when disabled. **Please refer to the Help file in the Omega software for more information regarding alarm settings**Trigger SettingsApplication of trigger settings to the OM-CP-RFTCTemp2000A allows the device to omit excess and/or unnecessary data.1. Select the device from the Connected Devices section in the software.2. Click the Properties button under the device tab at the top of the software.3. Under the Trigger tab in the Properties window, you can select a single point (window) or twopoint trigger.4. To enable a high trigger, select Enable High Trigger and enter the desired high setpoint.5. Toenable a low trigger select Enable Low Trigger and enter the desired low setpoint.5. To disable a high or low trigger, simply uncheck the applicable box.6. Click Apply to apply the trigger settings to the OM-CP-RFTCTemp2000A.Mounting InstructionsThe base provided with your OM-CP-RFTCTemp2000A can be used in two ways.use and mount the unit on a table top orhorizontal surface.The base can also sucurely snap to thebackside of the logger for wall mounting ifdesired (as shown right).There are 2 holes in the base to allow forscrews for mounting.Quick Start ManualTroubleshooting TipsWhy are my devices not appearing?If your OM-CP-RFTCTemp2000A isn’t showing up in the Connected devices panel, or you receive an error message while using the OM-CP-RFTCTemp2000A, try the following:• Check that your OM-CP-RFC1000-EXT is properly connected. For more information, see Troubleshooting Interface Cable problems (below).• Ensure that the battery is not discharged. For best voltage accuracy, use a voltage meter connected to the battery of the device. If you have one available, try switching the battery with a fresh 9V lithium.• Ensure that no other Omega software is running in the background• Ensure that you are using Omega data logger software.• Ensure that the Connected Devices panel is large enough to display devices. This can be verified by positioning the cursor on the edge of the Connected Devices panel until the resize cursor appears, then dragging the edge of the panel to resize itTroubleshooting Interface Cable problemsCheck that the software recognizes your OM-CP-RFC1000-EXT wireless receiverIf your device is not appearing in the Connected Devices list, it may be that the OM-CP-RFC1000-EXT is not properly connected.1. In the software, click the File Button , then click Options.2. In the Options window, click Communications.3. The Detected Interfaces box will list all of the available communication interfaces. If your OM-CP-RFC1000-EXT is listed there, then the software has correctly recognized and is ready to use it.Check that Windows recognizes your OM-CP-RFC1000-EXT wireless receiverIf the software does not recognise your OM-CP-RFC1000-EXT, there may be a problem with Windows or the USB drivers.1. In Windows, click Start, right-click Computer and choose Properties or you can press Windows+Breakas a keyboard shortcut.2. Click Device Manager in the left hand column.3. Double click Universal Serial Bus Controllers.4. Look for an entry for Datalogger Interface.5. If the entry is present, and there are no warning messages or icons, then windows has correctlyrecognized your OM-CP-RFC1000-EXT.6. If the entry is not present, or has an exclamation point icon next to it, you may need to install the USBdrivers. These are available on your software flash drive, and on the Omega website.Ensure that the USB end of the OM-CP-RFC1000-EXT is securely connected to the computer1. Locate the USB-A plug of your OM-CP-RFC1000-EXT.2. If the interface cable is connected to your PC, unplug it.3. Wait ten seconds, then reinsert it.4. Check to make sure that the red LED is lit, indicating a successful connection.OM-CP-RFTCTemp2000AProduct MaintenanceBattery ReplacementMaterials: OM-CP-BAT1031. On the bottom of the enclosure, open the battery compartment by pulling in on the cover tab.2. Remove the battery by pulling it from the compartment.3. Install the new battery, taking note of the polarity.4. Push the cover closed until it clicks.RecalibrationStandard recalibration for the OM-CP-RFTCTemp2000A is two points, 25°C and 60°C for the internal channel (ambient), and 0mV for the thermocouple (remote) channel. Recalibration is recommended annually for any Omega data logger; a reminder is automatically displayed in the software when the device is due.Still need help? For more troubleshooting tips and information, refer to the built in help section visit us online at or contact us for support at 1 (800) 872-9436.* Remote Channel Range, Resolution & AccuracyThermocoupleRange (°C)Resolution Accuracy J -210 to +7600.1°C +0.5°C K -270 to +13700.1°C +0.5°C T -270 to +4000.1°C +0.5°C E -270 to +9800.1°C +0.5°C R -50 to +17600.5°C +2.0°C S -50 to +17600.5°C +2.0°C B +50 to +18200.5°C +2.0°C N-270 to +13000.1°C+0.5°CBattery WarningWARNING: MAY LEAK, FLAME OR EXPLODE IF DISASSEMBLED, SHORTED, CHARGED, CONNECTED TOGETHER, MIXED WITH USED OR OTHER BATTERIES, AND/OR EXPOSED TO FIRE/HIGH TEMPERATURE. DISCARD USED BATTERY PROMPTLY , KEEP OUT OF REACH OF CHILDREN.Specifications subject to change.See Omega’s terms and conditions at Quick Start ManualOM-CP-RFC1000-EXT Wireless TransceiverQuick Start ManualProduct OverviewThe OM-CP-RFC1000-EXT is designed with a high powered transceiver that has a substantially long transmission range, meaning better performance in occluded environments (ovens, refrigerators, etc.). This OM-CP-RFC1000-EXT also includes an external antenna, allowing more flexibility with mounting positions in both orientation and proximity to metal walls. This may be used as a repeater, or directly plugged into the PC.Transmission DistanceThe OM-CP-RFC1000-EXT transmits to other OM-CP-RFC1000-EXTs up to 4000 feet maximum typical outdoors/line of sight, 1000 feet maximum typical indoors/urban. The OM-CP-RFC1000-EXT transmits to data loggers up to 2000 feet maximum typical outdoors/line of sight, 500 feet maximum typical indoors/urban. The OM-CP-RFC1000-EXT can connect to a maximum of 64 data loggers. The OM-CP-RFC1000-EXT transmits on a frequency of 2.405GHz - 2.475 GHz.Operating EnvironmentThe OM-CP-RFC1000-EXT is rated for use in an environment with temperatures from -20°C to 85°C and a humidity range of 0% to 95% RH non-condensing. The OM-CP-RFC1000-EXT is rated IP40 and is protected against solids that are greater than 1mm in size. This device is not water resistant.LEDsThe red LED indicates that the device has power. The green LED will blink when communicating with other Omega devices.Installation GuideInstalling the SoftwareInsert the Software CD or USB Flash Drive into a Windows PC. If the autorun does not appear, locate the drive on the computer and double click on Autorun.exe. Install the Omega software and USB Interface Drivers (under Drivers and Third Party Tools).The software can also be downloaded from . Deploying and Activating Devices1. Plug the OM-CP-RFC1000-EXT into the USB port on the base station computer. (Additional OM-CP-RFC1000-EXTs can be used as repeaters to transmit over greater distances)2. If using multiple OM-CP-RFC1000-EXTs plug each one into a wall outlet in the desired locations. (Iftransmitting over a distance greater than 1000 feet indoors or 4000 feet outdoors or there are walls/obstacles/ corners that need to be maneuvered around, set up additional OM-CP-RFC1000-EXTs as needed.)3. Verify that the data loggers are in wireless transmission mode. (See Channel Programming steps above)On a Windows PC, launch the Omega data logger software program. All active data loggers will be listed in the software showing that the device(s) are recognized.4. To activate the data loggers, click on one to highlight, then click the Claim icon, and then click the Starticon. Do this for each logger in the list that needs to be activate.Still need help? For more troubleshooting tips and information, refer to the built in help section visit us online at or contact us for support at 1 (800) 872-9436.Mounting InstructionsFor best wireless performance, both the OM-CP-RFC1000-EXT and the Omega data loggers should be mounted in the same orientation. This usually means that the external antenna should be pointing straight up.The antenna can pivot to accommodate either a wall mount or a desk mount.Channel 11Channel 12Channel 13Channel 14Channel 15Channel 16Channel 17Channel 18Channel 19Channel 20Channel 21Channel 22Channel 23Channel 24Channel 25Channel 26Follow the instructions below to configure the channel settings of the Omega Data Loggers.OM-CP-RFC1000-EXT: To program the channel on an OM-CP-RFC1000-EXT, first unplug the OM-CP-RFC1000-EXT. Use a Phillips head screwdriver to unscrew the enclosure. The dip switches are located on the front of the PCB circuit board. Change the dip switches to match the photo. Reconnect the OM-CP-RFC1000-EXT.OM-CP-RFTCTemp2000A: To program the channel on the OM-CP-RFTCTemp2000A data logger, start by switching the wireless mode to OFF by holding down the Wireless button on the data logger for 5 seconds. 1.Use the USB Cable, plug the USB end of the cable into an available USB port on the PC.2.Plug the opposite end of the cable into the communication port on the OM-CP-RFTCTemp2000A.3.Open the Omega data logger Software. Locate and select the OM-CP-RFTCTemp2000A in the Connect Devices panel. 4.In the Device tab, click the Properties icon. The Properties screen will display information about the device including Wireless setting. 5. Under the Wireless tab, select a desired channel (11-25) that will match with the OM-CP-RFC1000-EXT.Save all changes, disconnect the data logger, and return the device to wireless mode by holding down the Wireless button for 5 seconds.Channel ProgrammingThe OM-CP-RFC1000-EXT transmits data on the 2.4GHz band, channel 11. Each Omega Wireless Data Logger and OM-CP-RFC1000-EXT has a set of dip switches with which the channel may be programmed.Any Omega data logger or OM-CP-RFC1000-EXT that is on the same network are required to use the same channel. If they are not on the same channel, the devices will not communicate with one another.Different wireless channels may be used to create multiple networks in one area, or to avoid wirelessinterference from other devices. The images below show the orientations available of the switches for each channel. Channel 26 (all switches in the up position) is not supported.Quick Start ManualOM-CP-RFC1000-EXTTroubleshooting TipsWhy is the wireless data logger not appearing in the software?If the OM-CP-RFTCTemp2000A doesn’t appear in the Connected Devices panel, or an error message is received while using the OM-CP-RFTCTemp2000A, try the following:• Check that the OM-CP-RFC1000-EXT is properly connected. For more information, see Troubleshooting Interface Cable problems (below).• Ensure that the battery is not discharged. For best voltage accuracy, use a voltage meter connected to the battery of the device. If possible, try switching the battery with a new 9V lithium.• Ensure that no other Omega data logging software is running in the background.• Ensure that the most current Omega data logging software is being used.• Ensure that the Connected Devices panel is large enough to display devices. This can be verified by positioning the cursor on the edge of the Connected Devices panel until the resize cursor appears, then dragging the edge of the panel to resize it. The screen layout may also be reset in the options menu by selecting File, Options, and scrolling to the bottom.Troubleshooting Interface Cable problemsCheck that the software properly recognizes the connected OM-CP-RFC1000-EXT wireless receiver.If the wireless data logger is not appearing in the Connected Devices list, it may be that the OM-CP-RFC1000-EXT is not properly connected.1. In the software, click the File button, then click Options.2. In the Options window, click Communications.3. The Detected Interfaces box will list all of the available communication interfaces. If the OM-CP-RFC1000-EXT is listed here, then the software has correctly recognized and is ready to use it.Check that Windows recognizes the connected OM-CP-RFC1000-EXT wireless receiver.If the software does not recognise the OM-CP-RFC1000-EXT, there may be a problem with Windows or the USB drivers.1. In Windows, click Start, right-click Computer and choose Properties or press Windows+Break asa keyboard shortcut.2. Click Device Manager in the left hand column.3. Double click Universal Serial Bus Controllers.4. Look for an entry for Data logger Interface.5. If the entry is present, and there are no warning messages or icons, then windows has correctlyrecognized the connected OM-CP-RFC1000-EXT.6. If the entry is not present, or has an exclamation point icon next to it, the USB drivers may need to beinstalled. These are available on the software flash drive included with the OM-CP-RFC1000-EXT, and on the Omega website.Ensure that the USB end of the OM-CP-RFC1000-EXT is securely connected to the computer.1. Locate the USB-A plug of the OM-CP-RFC1000-EXT.2. If the interface cable is connected to the PC, unplug it. Wait ten seconds.3. Reconnect the cable to the PC.4. Check to make sure that the red LED is lit, indicating a successful connection.Quick Start ManualOM-CP-RFC1000-EXT General SpecificationsOM-CP-RFTCTemp2000ACompliance Information• “This device complies with Part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) this device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation.”• “To satisfy FCC RF Exposure requirements for mobile and base station transmission devices, a separation distance of 20cm or more should be maintained between the antenna of this device and persons during operation. To ensure compliance, operation at closer than this distance is not recommended. The antenna(s) used for this transmitter must not be co-located or operating in conjunction with any other antenna or transmitter.”• “This device complies with Industry Canada license-exempt RSS standard(s). Operation is subject to the following two conditions: (1) this device may not cause interference, and (2) this device must accept any interference, including interference that may cause undesired operation of the device.Le présent appareil est conforme aux CNR d’Industrie Canada applicables aux appareils radio exempts de licence. L’exploitation est autorisée aux deux conditions suivantes: (1) l’appareil ne doit pas produire de brouillage, et (2) l’utilisateur de l’appareil doit accepter tout brouillage radioélectrique subi, même si le brouillage est susceptible d’en compromettre le fonctionnement.”• “Under Industry Canada regulations, this radio transmitter may only operate using an antenna of a type and maximum (or lesser) gain approved for the transmitter by Industry Canada. To reduce potential radio interference to other users, the antenna type and its gain should be so chosen that the equivalent isotropically radiated power (e.i.r.p.) is not more than that necessary for successful communication.Conformément à la réglementation d’Industrie Canada, le présent émetteur radio peut fonctionner avec une antenne d’un type et d’un gain maximal (ou inférieur) approuvé pour l’émetteur par Industrie Canada. Dans le but de réduire les risques de brouillage radioélectrique à l’intention des autres utilisateurs, il faut choisir le type d’antenne et son gain de sorte que la puissance isotrope rayonnée équivalente (p.i.r.e.) ne dépasse pas l’intensité nécessaire à l’établissement d’une communication satisfaisante.”。

S E R V I C E A N D S U P P O RT D U R I N G E V E R Y S T E P O F T H E P R O C E S S . O n l y L e v i t o n h a s t h e s e r v i c e a n d s u p p o r t t o h e l p y o u c r e a t e a l i g h t i n g c o n t r o l s y s t e m t h a t d o e s e x a c t l y w h a t y o u w a n t i t t o d o w h i l e s a v i n g e l e c t r i c i t y , m e e t i n g c o d e s a n d s t a n d a r d s , a n de v e n g a r n e r i n g r e b a t e s .E X C L U S I V E W E A L T H OF R E S O U R C E S :D o l l a r s & S e n s o r s ® O n l i n eE n e r g y A u d i t T o o l — m a k e s e n e r g y a u d i t s e a s i e r t h a n e v e r — u s e y o u r s m a r t d e v i c e (A n d r o i d , A p p l e ,W i n d o w s o r B l a c k b e r r y ) t o e n t e r a u d i t i n f o r m a t i o n a n d y o u r d e s k t o p t o g e n e r a t e R O I r e p o r t s , a n a l y s e s , B i l l o f M a t e r i a l s , a n d a s u b m i t t a l p a c k a g e — g o t o w w w .l e v i t o n .c o m /d o l l a r s a n d s e n s o r s • O c c u p a n c y S e n s o r L a y o u t S e r v i c e s — h a v e a t e a m o fe x p e r t s c r e a t e o c c u p a n c y s e n s o r l a y o u t s d i r e c t l y o n y o u r C A Dd r a w i n g s , c o m p le t e w i t h a L i s t of E q u i p m e n t a t n o c o s t —g o t o p o r t a l .l e v i t o n .c o m • L i g h t L o g g e r ® P r o g r a m — g e t a n a c c u r a t e e s t i m a t e o f y o u r e n e r g y -s a v i n g s p o t e n t i a l w i t h t h i s e x c l u s i v e p a y b a c k a n a l y s i st o o l — g o t o w w w .l e v i t o n .c o m /l o g g e r• e z -L e a r n ™ — g e t L e v i t o n s m a r t f r o m t h e c o m f o r t o f y o u r h o m e o r o ffi c e w i t h t h i s e x c l u s i v e 24/7 o n l i n e t r a i n i n g —g o t o w w w .l e v i t o n .c o m /e z l e a r n • A S A P L i g h t i n g D e s i g n S o f t w a r e — p o i n t -a n d -c l i c k s o f t w a r ea l l o w s y o u t o q u i c k l y a n d s i m p l y d e s i g n , s p e c i f y a n d e n t e ro r d e r s — g o t o w w w .l e v i t o n .c o m /a s a p• F i n d m o r e e x c l u s i v e , n o -c o s t d e s i g n t o o l s a tw w w .l e v i t o n .c o m /l e s d e s i g n • L i g h t i n g c o n t r o l s p e c i a l i s t s a t y o u r d i s p o s a l • F i e l d s e r v i c e e n g i n e e r s f o r t o p -l e v e l s u p p o r t• F a c t o r y c o m m i s s i o n i n g s e r v i c e• D e d i c a t e d t e c h n i c a l s u p p o r t v i a p h o n e a t 1-800-959-6004L e v i t o n M a n u f a c t u r i n g C o ., I n c .L i g h t i n g & E n e r g y S o l u t i o n s201 N . S e r v i c e R d . M e l v i l l e , N Y 11747-3138T e c h L i n e : 1-800-824-3005 • F A X : 1-800-832-9538 • w w w .l e v i t o n .c o m /l e sL e v i t o n M a n u f a c t u r i n g o f C a n a d a , L t d .165 H y m u s B o u l e v a r d , P o i n t e C l a i r e , Q u e b e c H 9R 1E 9 T e l e p h o n e : 1-800-469-7890 • F A X : 1-800-563-1853L e v i t o n S . d e R .L . d e C .V .L a g o T a n a 43, M e x i c o D F , M e x i c o C P 11290T e l . (+52) 55-5082-1040 • F A X : (+52) 5386-1797 • w w w .l e v i t o n .c o m .m xV i s i t o u r W e b s i t e a t : w w w .l e v i t o n .c o m /l e s© 2015 L e v i t o n M a n u f a c t u r i n g C o ., I n c . A l l r i g h t s r e s e r v e d . S u b j e c t t o c h a n g e w i t h o u t n o t i c e .G -8431C /E 15-a k R E V M A Y 2015HOW TO PUT IT ALL TOGETHERTIP: A good way to visualize your wireless system is to imagine that the “wires” connecting each device are invisible wires or “unique addresses.”BASIC LEVNET RF SOLUTIONS3-Way or Multi-Location SwitchingSTEP 1Determine what LOADS you want to control — lighting, HVAC, lamp, TV, etc.LevNet RF Self-Powered Wireless TransmittersSTEP 3Pick the appropriate Wireless Self-Powered RF TRANSMITTER (sensor or switch)One WayCommunication1-10V DimmingTransmitter Hybrid ControlEnergy Code Compliant Plug Load Control Motor Load Control STEP 2Pick the appropriate RF RECEIVER Receives One Way CommunicationLevNet RF Wireless/Wired-In ReceiversLevNet RF ™902 MHz Wireless Self-Powered Solutions Product GuideTHE FUTURE IS ON ™Dimming with Occupancy and Daylighting - Hybrid Area Control Dimming with Daylighting - Hybrid Individual Fixture Control Plug Load Control OptionsLEVNET RF 902 MHZ WIRELESS SELF-POWERED SOLUTIONSSELF-POWERED + RADIO FREQUENCY = TRUE WIRELESSSelf-powered LevNet RF transmitters operate indefinitely without external power or batteries. Transmitters communicate with LevNet RF receivers via radio frequency. Operating in the 902 MHz band provides minimal competing traffic, enhanced reliability and greater transmission range over other wireless technologies.GREEN SOLUTIONSEnergy Savings• Lowest power consumption on wireless receivers at less than one Watt per device• Place virtually anywhere and control any compatible wireless device within range• Self-powered and self-charging, uses zero external power consumption to operateMaterial Savings• Reduce materials and time spent on installation with no new wires to run• Reduce monthly testing and maintenance costs* Leviton is part of the EnOcean Alliance. LevNet RF Solutions are compatible withother EnOcean Alliance wireless devices.WIRED VS. WIRELESS COSTSSENSORSSWITCHES CONTROL EXTENDERWSC12-M9NWSWDR-H9WWSS0S-S9WSS0S-D9WSS0S-R9WWSTLT-9D0Wall Switch Receivers x x x x x x Relay Receivers x x x x x x RF Receptacles x x x x x x Dimming Controllersxxxxx—PRODUCTCOMPATIBILITY MATRIXX - Indicates compatibilityPOWER PACKLINE VOLTAGE POWER PACKWSP20Memory Stores up to 20 Transmitter IDsPower Supply Input100-277VAC, 50/60 HzMax Loads/ Contact Rating General Duty: 20ATungsten (Incandescent): 20A Fluorescent Ballast: 20AMotor Load: 1HPPower Up State: Selectable N.O. or N.C.Output Channels 1 FORM A Latching Relay, N.O. or N.C.Time Delay 15 minAdditional ListingsETL (U.S.) UL 60730, UL 2043 Plenum rating,ETL (Canada): CSA C22.2 #1405,CE (International): IEC 60730RECEIVERSWALL SWITCHADVANCED WALL SWITCH RECEIVERSwith Color Change Kit WSS20-N9N | WSS20-G9NUse for larger rooms with multiple loads. Pairing for rocker, momentary and toggle.Input Voltage 120-230-277VACPowerConsumption 120V < 1/2 Watt; 277V < 2/3 Watt Memory Stores up to 20 Transmitter IDs Button Pairing Modes Rocker, Momentary and ToggleVacancy Confirmation 30 seconds Mode Presentation/Viewing Time Delay2 min (test); 10, 20, 30 minLoad RatingGeneral Duty: 10A LED: 400W @ 120VIncandescent: 800W @ 120VFluorescent Ballasts: 1200VA @ 120V, 2700VA @ 277VMotor: 1/4 HP Load @ 120VFor non-neutral models: 25W minimum load requiredAdditional ListingsETL/cETL: UL508, CA Title 24 Compliant,CAN/CSA C22.2 #14All WSS20 models ship with a Color Change Kit which includes a White, Ivory and Light Almond faceplate.Gray and Ebony faceplates available in quantities of 25.1-10V DIMMING CONTROLLERS5A FIXTURE CONTROLLER WSD05-9D020A AREA CONTROLLER WSD20-9D0Memory Stores up to 20 Transmitter IDsPower Supply Input Rating 100-277VAC, 50/60 HzOutput Rating —10mA source Input Channels —1 - 1-10V input signal1 mA sourceOutput Channels 1 - latching FORM A relay,selectable N.O. or N.C. power up state1 - 1-10V output signal (sink 100mA, source 1mA)Load Rating5A20ARF RECEPTACLESPLITDUPLEX RECEIVERWSG15-S9WDUPLEX RECEIVER WSG15-D9WPower Supply 125VAC, 60Hz, 15APowerConsumption120VAC @ 10mA AC (320mW typical)Switched Side:Max Loads/Constant Ratings General Use/Resistive: 15A Incandescent: 1800W Inductive: 1800VA 1/2HP , 120VAC Controlled Single (Top)DualListingsCA Title 24 Compliant, ASHRAE Standard 90.1 2010Compliant, TR ReceptacleTRANSMITTERSRECEIVERSSENSORSCEILING MOUNT OCCUPANCY SENSORWSC12-M9NWALL MOUNT OCCUPANCY SENSORWSWDR-H9WCoverage 1,200 SF1600/2200 SFPowerConsumption Zero (Self-Powered)Transmission 60 seconds (+/- 10 sec)***************(5LUX);***************(10LUX);30 seconds @ 20FC (200 LUX)Minimum Light Required 5FC(50 LUX for auto-OFF only) 1.5FC (15 LUX)Minimum Charge Time to Begin Operation 1 minute @ 20FC (200 LUX)*************(15LUX);5 seconds @ 20FC (200 LUX)Maintain Charge Time 3 hours per 24 hours @ 20FC (200 LUX)Operating Life at Full Charge80 hours48 hoursAdditional Listings CA Title 24 Compliant, FCC Certified for Wireless Communication (U.S.), I.C. Certified (Canada)CONTROL EXTENDERCONTROL TRANSMITTERWSTLT-9D0Communicates with receivers that control virtually any ON/OFF devicePower Supply Input 100-277VAC, 50/60 Hz Addressing Factory set unique ID (1 of 4 billion)Additional ListingsUL 60730 (Safety), UL 2043 (Plenum),CSA C22.2#14-05 (Safety),CE-IEC 60730, CA Title 24 CompliantLevNet RF Self-Powered Wireless Solutions Frequency 902 MHzRange 50-150 feet (Design to 75 feet)Listings FCC Certified for Wireless Communication(U.S.), I.C. Certified (Canada)WarrantyLimited 5-yearPUTTING TOGETHER A LEVNET RF 902 MHZ SYSTEMWALL STATIONSSINGLE ROCKERDECORA ® WALL STATION WSS0S-S9xDUAL ROCKER DECORA WALL STATION*WSS0S-D9x HANDHELD 4-BUTTON REMOTE WSS0S-R9W Buttons 2 Buttons (1 Rocker)4 Buttons (2 Rockers)4 Buttons (2 Rockers)Output Channels Only limited by number of Receivers in rangeAddressingFactory set unique ID (1 of 4 billion)* Available in White (-W), Ivory (-I), Light Almond (-T), Gray (-G) and Ebony (-E).Note: Wall Stations are both switches and dimmers depending on the receiver they are paired to -see the Wall Station data sheet for details.1342Determine what LOADS you want to control - lighting, HVAC, lamp, TV, etc.Pick the appropriate RF RECEIVER mounting style Pick the appropriate wireless self-powered RF TRANSMITTER (sensor or switch)PAIRthe devices to communicate with each other DID YOU KNOW?LevNet RF wireless self-powered sensors and switchesuse zero power for zero utility cost.In standby power consumption alone, LevNet RF saves 70%over the competition month after month after the install. LevNet RFuses less than one Watt in standby mode to operate a receiver.LevNet RF offers a no-neutral design for ALL retrofit installations.You receive LEED points for wireless control AND no batterieswhen you install LevNet RF wireless self-powered sensors.。

DATA SHEET RF over Glass (RFoG)RFoG and RFPON ONU (R-ONU)Powering Solutions Most CommScope RFoG Optical Network Unit (R ‐ONU) devices require external power for operation. Separately sold powering solutions include compact low ‐cost high reliability wall ‐mounted AC ‐to ‐DC adapters with 12VDC or 15 VDC outputs and standard female "F" type connectors having nominal AC input voltages of 120 or 100 to 240 Volts AC. Input mains connectors fit NEMA ‐USA, EU, and UK style connectors common to various worldwide geographical regions. NEMA ‐USA mains plugs offer a wall plate mounting lug that ensures a secure installation. The required power supply depends on the R ‐ONU device being powered.A battery back ‐up Uninterruptible Power Supply (UPS) supporting 100 to 240 VAC input range is also available, for continuous operation during AC power failures. The PS1801B ‐00 battery for the PS1811U ‐01 UPS is sold separately. All power supplies feature “F” type female DC connectors for compatibility with the R ‐ONU connectors.•Designed for CommScope RFoG and RFPONR ‐ONU solutions•CSHMPIE high isolation 1.8 GHz power inserter•AC/DC wall adaptersPS1921W ‐10 SMPS with universal AC inputvoltage and connectors for NEMA ‐USA, EU,and UK applications. Meets international andUnited States DOE Class VI efficiencyspecificationPS1911W (120 VAC NEMA/US 1‐15P) (Maynot meet local efficiency regulations, thuslimiting use in certain countries.)All models above feature type “F” female DCoutput connectors•Uninterruptible Power SupplyUp to 20 hours of standard operation120 or 230 VAC inputType “F” female DC output connector•High reliability for long ‐term service FEATURESPS1921W ‐10PS1911PS1811U ‐01 UPSCSHMPIE PowerInserter (1.8GHz)PS1921W‐10: Universal AC voltage input range (100–240 VAC)•Multi‐country mains connector types•Meets International and USA Department of Energy (DOE) Class VI efficiency specifications•Connects directly to the R‐ONU, eliminating the PS1900‐ADP DC to F‐type adapter•Supports all CommScope CP8x R‐ONUs requiring external power suppliesPS1911W‐00: 120 VAC with USA NEMA 1‐15P AC connector and wall plate securing lugMay not meet local efficiency regulations, thus limiting use in certain countries. Operating temperature range may be less than that of the powered ONU.•Supports CommScope standard (non‐OBI‐free) R‐ONUsPS1811U‐01: Uninterruptable Power Supply (UPS)•Supports all CommScope CP8x R‐ONUsCSHMPIE Power InserterClass‐leading power inserter that provides maximum isolation between the power supply and the RF ports, preventing ingress when the R‐ONU is remotely powered via the RF coax. A Power Inserter is included with standard SDU and MDU non‐OBI‐freeR‐ONUs, not including the CP8600 models which have built‐in power supplies.SPECIFICATIONSPS1911W‐00 AC Wall Adapter120 V AC(nominal) USA type adapter with 12 V DC output on “F” connectorAC Input Voltage 108─132 V AC, 60 HzAC Input Connector NEMA 1‐15P (NP)DC Output Voltage12 V nominal @ 500 mADC Output Connector ANSI/SCTE 02:2006 type F FemaleSurge Protection1 kV min (per IEEE/ANSI C62.41)Safety UL 13210/CSA C22.2 No. 223‐M91Operating Temperature‐10°to +40°C (+14°to +104°F) NOTE: Operating range may be less than that of the powered ONU. Indoor mountingsuggested.Storage Temperature‐20°to +80°C (‐4°to +176°F)Humidity5% to 95% non‐condensingDimensions 2.3” W x 3.0” H x 2.0” D (5.8 cm x 7.6 cm x 5.0 cm)Weight, typ1 lb. (0.45 kg)Efficiency May not meet certain country regulations. Check local regulations before use.PS1921W‐10 Universal Power Supply Kit Wall mount AC/DC adapter provided with interchangeable AC adapter plates for US, EU, and UK applicationsAC Input Voltage100─240 V AC, 50/60 HzAC Input Connector Three interchangeable adapters: NEMA 1‐15P (NP), CEE 7/16 and BS1363 (USA, EU, and UK styles). USA adapterfeatures a mounting lug to secure adapter to the wall outlet.DC Output15 V DC@ 1.5 A maxDC Output Connector ANSI/SCTE 02.2006 compliant F‐type Coax ConnectorSurge Protection6 kV combination wave per IEEE/ANSI C62.41Operating Temperature‐10°to +40°C (14°to 104°F) @ 1.5 A max output current. NOTE: Operating range may be less than that of the poweredONU. Indoor mounting suggested.Storage Temperature‐40°to +85°C (‐40°to 185°F)Operating/Storage Humidity5% to 95% RH, non‐condensingDimensions 1.69" W x 3.35" H x 1.93" D (4.3 cm x 8.5 cm x 4.9 cm)Weight0.26 lb. (0.12 kg)EMC CE, BSMI, FCC, and VCCI compliantSafety IEC 60950‐1; EN 60950‐1; UL 60950‐1Efficiency Meets International and US DOE Class VI SpecificationsCSHMPIE Power InserterOperating Frequency5–1800 MHzInsertion loss RF to RF + Power1 dB maxReturn Loss20 dB (5 MHz to 1218 MHz)Isolation5–800 MHz 800–1218 MHz 1275–1800 MHz 75 dB min 70 dB min 65 dB minRF Shielding105 dB min per ANSI/SCTE 48‐2 2008 Operating Temperature‐40°to +65°C (‐40°to +149°F)Dimensions (L x W x H) 2.2 in x 1.57 in x 0.67 in (55.9 x 40.0 x 14.5 mm) Weight 1.0 oz (28 g) typRoHS Compliant YesPS1811U‐01 Uninterruptible Power Supply (UPS) Please review the individual data sheet for complete specifications.AC Input Voltage100–240 V RMS @ 0.5 A max, 50/60 HzInput Frequency50/60 HzAC Input Connector IEC 320/C6 inletPower Cord IEC 320/C5 to NEMA 5‐15Output Voltage12.0 V DC nominal (battery voltage upon loss of AC)Operational Output Power8 W maxOutput Connector ANSI/SCTE 02.2006 compliant F‐type Coax ConnectorDimensions 6.6” W x 7.75” H x 3.3” D (16.7 cm x 19.0 cm x 8.33 cm)Weight 1.2 lb (0.54 kg); battery: 5.7 lb (2.6 kg)Operating Temperature‐20°to +45°C (‐4°to 113°F) NOTE: Operating range may be less than that of the powered ONU. Indoor mountingsuggested.Storage Temperature‐20°to +45°C (‐4°to +113°F)Humidity5% to 95% non‐condensingSafety UL/CSA/EN 60950‐1EMC FCC Part 15 Class B, EN 55022, EN 55024Environmental CE Mark, RoHS compliantModel Identification Alpha FlexPoint FPR1208‐FPS1801B‐00 UPS Battery (Sold separately)12 V DC Standby Battery for PS1811U‐01 UPS7.2 AH AGM batteryProvides approximately 10 hours of backup at 6 W (or 20 hours at 3 W) to 25% reserve point shut‐off, based on new,fully‐charged batteryHot‐swappableRecharge time 18 hours to 90%Uses maintenance‐free sealed‐lead acidBattery Storage‐20°to +40°C (‐4°to 104°F), six months max storage duration at +25°C (+77°F) without a recharge SPECIFICATIONSRELATED PRODUCTSOR3144H, OR41x8H Diplexer/Receivers CH3000 Chassis and NH4000 VHub RFoG modulesXE4202M Remote OLT(R‐OLT)RFoG CP8xxx ONUsContact Customer Care for product information and sales:•United States: 866‐36‐ARRIS•International: +1‐678‐473‐5656Note: Specifications are subject to change without notice.Copyright Statement:©2022CommScope,Inc.All rights reserved.ARRIS and the ARRIS logo are trademarks of CommScope,Inc.and/or its affiliates.All other trademarks are the property of their respective owners.No part of this content may be reproduced in any form or by any means or used to make any derivative work(such as translation,transformation,or adaptation)without written permission from CommScope,Inc and/or its affiliates (“CommScope”).CommScope reserves the right to revise or change this content from time to time without obligation on the part of CommScope to provide notification of such revision or change.87‐10592‐RevN_RFoG‐and‐RFPON‐Powering‐Solutions。

测井符号英文名称中文名称Rt true formation resistivity. 地层真电阻率Rxo flushed zone formation resistivity 冲洗带地层电阻率Ild deep investigate induction log 深探测感应测井Ilm medium investigate induction log 中探测感应测井Ils shallow investigate induction log 浅探测感应测井Rd deep investigate double lateral resistivity log 深双侧向电阻率测井Rs shallow investigate double lateral resistivity log 浅双侧向电阻率测井RMLL micro lateral resistivity log 微侧向电阻率测井CON induction log 感应测井AC acoustic 声波时差DEN density 密度CN neutron 中子GR natural gamma ray 自然伽马SP spontaneous potential 自然电位CAL borehole diameter 井径K potassium 钾TH thorium 钍U uranium 铀KTH gamma ray without uranium 无铀伽马NGR neutron gamma ray 中子伽马5700系列的测井项目及曲线名称Star Imager 微电阻率扫描成像CBIL 井周声波成像MAC 多极阵列声波成像MRIL 核磁共振成像TBRT 薄层电阻率DAC 阵列声波DVRT 数字垂直测井HDIP 六臂倾角MPHI 核磁共振有效孔隙度MBVM 可动流体体积MBVI 束缚流体体积MPERM 核磁共振渗透率Echoes 标准回波数据T2 Dist T2分布数据TPOR 总孔隙度BHTA 声波幅度BHTT 声波返回时间Image DIP 图像的倾角COMP AMP 纵波幅度Shear AMP 横波幅度COMP ATTN 纵波衰减Shear ATTN 横波衰减RADOUTR 井眼的椭圆度Dev 井斜原始测井曲线代码AMP5 第五扇区的声幅值AMP6 第六扇区的声幅值AMVG 平均声幅AO10 阵列感应电阻率AO20 阵列感应电阻率AO30 阵列感应电阻率AO60 阵列感应电阻率AO90 阵列感应电阻率AOFF 截止值AORT 阵列感应电阻率AORX 阵列感应电阻率APLC 补偿中子AR10 方位电阻率AR11 方位电阻率AR12 方位电阻率ARO1 方位电阻率ARO2 方位电阻率ARO3 方位电阻率ARO4 方位电阻率ARO5 方位电阻率ARO6 方位电阻率ARO7 方位电阻率ARO8 方位电阻率ARO9 方位电阻率AT10 阵列感应电阻率AT20 阵列感应电阻率AT30 阵列感应电阻率AT60 阵列感应电阻率AT90 阵列感应电阻率ATAV 平均衰减率ATC1 声波衰减率ATC2 声波衰减率ATC3 声波衰减率ATC4 声波衰减率ATC5 声波衰减率ATC6 声波衰减率ATMN 最小衰减率ATRT 阵列感应电阻率ATRX 阵列感应电阻率AZ 1号极板方位AZ1 1号极板方位AZI 1号极板方位AZIM 井斜方位BGF 远探头背景计数率BGN 近探头背景计数率BHTA 声波传播时间数据BHTT 声波幅度数据BLKC 块数BS 钻头直径BTNS 极板原始数据C1 井径C2 井径C3 井径CAL 井径CAL1 井径CAL2 井径CALI 井径CALS 井径CASI 钙硅比CBL 声波幅度CCL 磁性定位CEMC 水泥图CGR 自然伽马CI 总能谱比CMFF 核磁共振自由流体体积CMRP 核磁共振有效孔隙度CN 补偿中子CNL 补偿中子CO 碳氧比CON1 感应电导率COND 感应电导率CORR 密度校正值D2EC 200兆赫兹介电常数D4EC 47兆赫兹介电常数DAZ 井斜方位DCNT 数据计数DEN 补偿密度DEN_1 岩性密度DTST 斯通利波时差ECHO 回波串ECHOQM 回波串ETIMD 时间FAMP 泥浆幅度FAR 远探头地层计数率FCC 地层校正FDBI 泥浆探测器增益FDEN 流体密度FGAT 泥浆探测器门限FLOW 流量FPLC 补偿中子FTIM 泥浆传播时间GAZF Z轴加速度数据GG01 屏蔽增益GG02 屏蔽增益GG03 屏蔽增益GG04 屏蔽增益GG05 屏蔽增益GG06 屏蔽增益GR 自然伽马GR2 同位素示踪伽马HAZI 井斜方位HDRS 深感应电阻率HFK 钾HMRS 中感应电阻率HSGR 无铀伽马HTHO 钍HUD 持水率HURA 铀IDPH 深感应电阻率IMPH 中感应电阻率K 钾KCMR 核磁共振渗透率KTH 无铀伽马LCAL 井径LDL 岩性密度LLD 深侧向电阻率LLD3 深三侧向电阻率LLD7 深七侧向电阻率LLHR 高分辨率侧向电阻率LLS 浅侧向电阻率LLS3 浅三侧向电阻率LLS7 浅七侧向电阻率M1R10 高分辨率阵列感应电阻率M1R120 高分辨率阵列感应电阻率M1R20 高分辨率阵列感应电阻率M1R30 高分辨率阵列感应电阻率M1R60 高分辨率阵列感应电阻率M1R90 高分辨率阵列感应电阻率M2R10 高分辨率阵列感应电阻率M2R120 高分辨率阵列感应电阻率M2R20 高分辨率阵列感应电阻率M2R30 高分辨率阵列感应电阻率M2R60 高分辨率阵列感应电阻率M2R90 高分辨率阵列感应电阻率M4R10 高分辨率阵列感应电阻率M4R120 高分辨率阵列感应电阻率M4R20 高分辨率阵列感应电阻率M4R30 高分辨率阵列感应电阻率M4R60 高分辨率阵列感应电阻率M4R90 高分辨率阵列感应电阻率MBVI 核磁共振束缚流体体积MBVM 核磁共振自由流体体积MCBW 核磁共振粘土束缚水ML1 微电位电阻率ML2 微梯度电阻率MPHE 核磁共振有效孔隙度MPHS 核磁共振总孔隙度MPRM 核磁共振渗透率MSFL 微球型聚焦电阻率NCNT 磁北极计数NEAR 近探头地层计数率NGR 中子伽马NPHI 补偿中子P01 第1组分孔隙度P02 第2组分孔隙度P03 第3组分孔隙度PD6G 屏蔽电压PE 光电吸收截面指数PEF 光电吸收截面指数PEFL 光电吸收截面指数PERM-IND 核磁共振渗透率POTA 钾PPOR 核磁T2谱PPORB 核磁T2谱PPORC 核磁T2谱PR 泊松比PRESSURE 压力QA 加速计质量QB 磁力计质量QRTT 反射波采集质量R04 0.4米电位电阻率R045 0.45米电位电阻率R05 0.5米电位电阻率R1 1米底部梯度电阻率R25 2.5米底部梯度电阻率R4 4米底部梯度电阻率R4AT 200兆赫兹幅度比R4AT_1 47兆赫兹幅度比R4SL 200兆赫兹电阻率R4SL_1 47兆赫兹电阻率R6 6米底部梯度电阻率R8 8米底部梯度电阻率RAD1 井径（极板半径）RAD2 井径（极板半径）RAD3 井径（极板半径）RAD4 井径（极板半径）RAD5 井径（极板半径）RAD6 井径（极板半径）RADS 井径（极板半径）RATI 地层比值RB 相对方位RB_1 相对方位角RBOF 相对方位RD 深侧向电阻率RFOC 八侧向电阻率RHOB 岩性密度RHOM 岩性密度RILD 深感应电阻率RILM 中感应电阻率RLML 微梯度电阻率RM 钻井液电阻率RMLL 微侧向电阻率RMSF 微球型聚焦电阻率RNML 微电位电阻率ROT 相对方位RPRX 邻近侧向电阻率RS 浅侧向电阻率SDBI 特征值增益SFL 球型聚焦电阻率SFLU 球型聚焦电阻率SGAT 采样时间SGR 无铀伽马SICA 硅钙比SIG 井周成像特征值SIGC 俘获截面SIGC2 示踪俘获截面SMOD 横波模量SNL 井壁中子SNUM 特征值数量SP 自然电位SPER 特征值周期T2 核磁T2谱T2-BIN-A 核磁共振区间孔隙度T2-BIN-B 核磁共振区间孔隙度T2-BIN-PR 核磁共振区间孔隙度T2GM T2分布对数平均值T2LM T2分布对数平均值TEMP 井温TH 钍THOR 钍TKRA 钍钾比TPOR 核磁共振总孔隙度TRIG 模式标志TS 横波时差PORH 油气重量NEWSANDBULK 出砂指数NEWSANDPERM 渗透率NEWSANDSW 含水饱和度NEWSANDSH 泥质含量NEWSANDCALO 井径差值NEWSANDCL 粘土含量NEWSANDDHY 残余烃密度NEWSANDSXO 冲洗带含水饱和度NEWSANDDA 第一判别向量的判别函数NEWSAND DB 第二判别向量的判别函数NEWSAND DAB 综合判别函数NEWSANDCI 煤层标志NEWSANDCARB 煤的含量NEWSANDTEMP 地层温度NEWSANDQ 评价泥质砂岩油气层产能的参数NEWSAND PI 评价泥质砂岩油气层产能的参数NEWSAND SH 泥质体积CLASSSW 总含水饱和度CLASSPOR 有效孔隙度CLASSPORG 气指数CLASSCHR 阳离子交换能力与含氢量的比值CLASS CL 粘土体积CLASSPORW 含水孔隙度CLASSPORF 冲洗带饱含泥浆孔隙度CLASSCALC 井径差值CLASSDHYC 烃密度CLASSPERM 绝对渗透率CLASSPIH 油气有效渗透率CLASSPIW 水的有效渗透率CLASSCLD 分散粘土体积CLASSCLL 层状粘土体积CLASSCLS 结构粘土体积CLASSEPOR 有效孔隙度CLASSESW 有效含水饱和度CLASSTPI 钍钾乘积指数CLASSPOTV １００％粘土中钾的体积CLASSCEC 阳离子交换能力CLASSQV 阳离子交换容量CLASSBW 粘土中的束缚水含量CLASSEPRW 含水有效孔隙度CLASSUPOR 总孔隙度，UPOR=EPOR+BW CLASS HI 干粘土骨架的含氢指数CLASSBWCL 粘土束缚水含量CLASSTMON 蒙脱石含量CLASSTILL 伊利石含量CLASSTCHK 绿泥石和高岭石含量CLASSVSH 泥质体积CLASSVSW 总含水饱和度CLASSVPOR 有效孔隙度CLASSVPOG 气指数CLASSVCHR 阳离子交换能力与含氢量的比值CLASS VCL 粘土体积CLASSVPOW 含水孔隙度CLASSVPOF 冲洗带饱含泥浆孔隙度CLASS VCAC 井径差值CLASSVDHY 烃密度CLASSVPEM 绝对渗透率CLASSVPIH 油气有效渗透率CLASSVPIW 水的有效渗透率CLASSVCLD 分散粘土体积CLASSVCLL 层状粘土体积CLASSVCLS 结构粘土体积CLASSVEPO 有效孔隙度CLASSVESW 有效含水饱和度CLASSVTPI 钍钾乘积指数CLASSVPOV １００％粘土中钾的体积CLASS VCEC 阳离子交换能力CLASSVQV 阳离子交换容量CLASSVBW 粘土中的束缚水含量CLASS VEPR 含水有效孔隙度CLASSVUPO 总孔隙度CLASSVHI 干粘土骨架的含氢指数CLASS VBWC 粘土束缚水含量CLASSVTMO 蒙脱石含量CLASSVTIL 伊利石含量CLASSVTCH 绿泥石和高岭石含量CLASS QW井筒水流量PLIQT井筒总流量PLISK射孔井段PLIPQW单层产水量PLIPQT单层产液量PLIWEQ 相对吸水量ZRPMPEQ 相对吸水强度ZRPMPOR 孔隙度PRCOPORW 含水孔隙度PRCOPORF 冲洗带含水孔隙度PRCO PORT 总孔隙度PRCOPORX 流体孔隙度PRCOPORH 油气重量PRCOBULK 出砂指数PRCOHF 累计烃米数PRCOPF 累计孔隙米数PRCOPERM 渗透率PRCOSW 含水饱和度PRCOSH 泥质含量PRCOCALO 井径差值PRCOCL 粘土含量PRCODHY 残余烃密度PRCOSXO 冲洗带含水饱和度PRCOSWIR 束缚水饱和度PRCOPERW 水的有效渗透率PRCOPERO 油的有效渗透率PRCOKRW 水的相对渗透率PRCOKRO 油的相对渗透率PRCOFW 产水率PRCOSHSI 泥质与粉砂含量PRCOSXOF 199＊SXO PRCOSWCO 含水饱和度PRCOWCI 产水率PRCOWOR 水油比PRCOCCCO 经过PORT校正后的C／O值PRCO CCSC 经过PORT校正后的SI／CA值PRCO CCCS 经过PORT校正后的CA／SI值PRCO DCO 油水层C／O差值PRCOXIWA 水线视截距PRCOCOWA 视水线值PRCOCONM 视油线值PRCAC 声波时差数据计数补偿密度A1R1 T1R1声波幅度A1R2 T1R2声波幅度A2R1 T2R1声波幅度A2R2 T2R2声波幅度AAC 声波附加值AAVG 第一扇区平均值AF10 阵列感应电阻率AF20 阵列感应电阻率AF30 阵列感应电阻率AF60 阵列感应电阻率AF90 阵列感应电阻率AFRT 阵列感应电阻率AFRX 阵列感应电阻率AIMP 声阻抗AIPD 密度孔隙度AIPN 中子孔隙度AL 声波（速度）测井AMAV 声幅AMAX 最大声幅AMIN 最小声幅AMP1 第一扇区的声幅值AMP2 第二扇区的声幅值AMP3 第三扇区的声幅值AMP4 第四扇区的声幅值AMP5 第五扇区的声幅值AMP6 第六扇区的声幅值AMVG 平均声幅AO10 阵列感应电阻率AO20 阵列感应电阻率AO30 阵列感应电阻率AO60 阵列感应电阻率AO90 阵列感应电阻率AOFF 截止值AORT 阵列感应电阻率AORX 阵列感应电阻率APLC 补偿中子AR10 方位电阻率AR11 方位电阻率AR12 方位电阻率ARO1 方位电阻率ARO2 方位电阻率ARO3 方位电阻率ARO4 方位电阻率ARO5 方位电阻率ARO6 方位电阻率ARO7 方位电阻率ARO8 方位电阻率ARO9 方位电阻率AT10 阵列感应电阻率AT20 阵列感应电阻率AT30 阵列感应电阻率AT60 阵列感应电阻率AT90 阵列感应电阻率ATAV 平均衰减率ATC 声波衰减率ATC1 声波衰减率ATC2 声波衰减率ATC3 声波衰减率ATC4 声波衰减率ATC5 声波衰减率ATC6 声波衰减率ATMN 最小衰减率ATRT 阵列感应电阻率ATRX 阵列感应电阻率AZ 1号极板方位AZ1 1号极板方位AZI 1号极板方位AZIM 方位角AZIM 井斜方位BACBGF 远探头背景计数率BGN 近探头背景计数率BHC 补偿声波BHT 井底温度BHTA 声波传播时间数据BHTT 声波幅度数据BLKC 块数BS 钻头直径BTNS 极板原始数据BxC1 井径C2 井径C3 井径CAL 井径CAL 井径CAL1 井径CAL2 井径CALI 井径CALS 井径CASI 钙硅比CBL 声波幅度CCL 磁性定位CEC 阳离子交换能力CEMC 水泥图CET 水泥评价测井？CGR 自然伽马CI 总能谱比CL 粘土含量CLD 分散粘土体积CLL 层状粘土体积CLS 结构粘土体积CMFF 核磁共振自由流体体积CMRP 核磁共振有效孔隙度CN 中子CN 补偿中子CNL CNL井壁中子CNL 补偿中子CO 碳氧比CON 感应测井CON1 感应电导率COND 感应电导率CORR 密度校正值D2EC 200兆赫兹介电常数D4EC 47兆赫兹介电常数DAZ 井斜方位DEN 密度DEN_1 岩性密度DEPTH 测量深度DEV 井斜DEVI 井斜DFL 数字聚焦电阻率DHY 残余烃密度DHYC 烃密度DIA1 井径DIA2 井径DIA3 井径DIFF 核磁差谱DIP1 地层倾角微电导率曲线1 DIP1_1 极板倾角曲线DIP2 地层倾角微电导率曲线2 DIP2_1 极板倾角曲线DIP3 地层倾角微电导率曲线3 DIP3_1 极板倾角曲线DIP4 地层倾角微电导率曲线4 DIP4_1 极板倾角曲线DIP5 极板倾角曲线DIP6 极板倾角曲线DRH 密度校正值DRHO 密度补偿值DT 声波时差DT1 下偶极横波时差DT2 上偶极横波时差DT4P 纵横波方式单极纵波时差DT4S 纵横波方式单极横波时差DTL 声波时差DTST 斯通利波时差ECHO 回波串ECHOQM 回波串EPOR 有效孔隙度ESW 有效含水饱和度ETIMD 时间F 地层因数FAMP 泥浆幅度FAR 远探头地层计数率FCC 地层校正FDBI 泥浆探测器增益FDEN 流体密度FGAT 泥浆探测器门限FLOW 流量FPLC 补偿中子FTIM 泥浆传播时间GAZF Z轴加速度数据GG01 屏蔽增益GG02 屏蔽增益GG03 屏蔽增益GG04 屏蔽增益GG05 屏蔽增益GG06 屏蔽增益GR 自然伽马GR1 自然伽马？GR2 同位素示踪伽马HAC 高分辨率声波时差HAZI 井斜方位HDRS 深感应电阻率HF 累计烃米数HFK 钾HMRS 中感应电阻率HSGR 无铀伽马HTHO 钍HUD 持水率HURA 铀IDPH 深感应电阻率IES 感应测井？Ild(RILD) 深探测感应测井Ilm(RILM) 中探测感应测井Ils 浅探测感应测井IDPH 深感应电阻率IMPH 中感应电阻率ISF 球形聚焦测井K 钾KCMR 核磁共振渗透率KRO 油的相对渗透率KRW 水的相对渗透率KTH 无铀伽马LCAL 井径LDL 岩性密度LL 侧向测井？LL3 深三侧向电阻率LL7 深七侧向电阻率LL8 深八侧向电阻率LLD 深侧向电阻率LLD3 深三侧向电阻率LLD7 深七侧向电阻率LLD7、LLS7 七测向LLHR 高分辨率侧向电阻率LLS 浅侧向电阻率LLS3 浅三侧向电阻率LLS7 浅七侧向电阻率LSS 长源距声波测井M 胶结指数M1R10 高分辨率阵列感应电阻率M1R120 高分辨率阵列感应电阻率M1R20 高分辨率阵列感应电阻率M1R30 高分辨率阵列感应电阻率M1R60 高分辨率阵列感应电阻率M1R90 高分辨率阵列感应电阻率M2R10 高分辨率阵列感应电阻率M2R120 高分辨率阵列感应电阻率M2R20 高分辨率阵列感应电阻率M2R30 高分辨率阵列感应电阻率M2R60 高分辨率阵列感应电阻率M2R90 高分辨率阵列感应电阻率M4R10 高分辨率阵列感应电阻率M4R120 高分辨率阵列感应电阻率M4R20 高分辨率阵列感应电阻率M4R30 高分辨率阵列感应电阻率M4R60 高分辨率阵列感应电阻率M4R90 高分辨率阵列感应电阻率MBVI 核磁共振束缚流体体积MBVM 核磁共振自由流体体积MCBW 核磁共振粘土束缚水ML 微电位电阻率MK 微梯度电阻率ML1 微电位电阻率（微电极A0.025M0.025N-A0.05M）ML2 微梯度电阻率（微电极A0.025M0.025N-A0.05M）MLL 微侧向电阻率MPHE 核磁共振有效孔隙度MPHS 核磁共振总孔隙度MPRM 核磁共振渗透率MSFL 微球型聚焦电阻率N 饱和度指数NCNT 磁北极计数NEAR 近探头地层计数率NGR 中子伽马NGS 自然伽马能谱测井NLL 中子寿命测井NML 核磁共振测井NPHI 补偿中子OMRL 定向微电阻率测井P01 第1组分孔隙度P02 第2组分孔隙度P03 第3组分孔隙度P04 第4组分孔隙度P05 第5组分孔隙度P06 第6组分孔隙度P07 第7组分孔隙度P08 第8组分孔隙度P09 第9组分孔隙度P10 第10组分孔隙度P11 第11组分孔隙度P12 第12组分孔隙度P1AZ 1号极板方位P1AZ_1 2号极板方位P1BTN 极板原始数据P2BTN 极板原始数据P2HS 200兆赫兹相位角P3BTN 极板原始数据P4BTN 极板原始数据P4HS 47兆赫兹相位角P5BTN 极板原始数据P6BTN 极板原始数据PAD1 1号极板电阻率曲线PAD2 2号极板电阻率曲线PAD3 3号极板电阻率曲线PAD4 4号极板电阻率曲线PAD5 5号极板电阻率曲线PAD6 6号极板电阻率曲线PADG 极板增益PD6G 屏蔽电压PE 光电吸收截面指数PEF 光电吸收截面指数PEFL 光电吸收截面指数PERM 渗透率Perm / K 渗透率PERM-IND 核磁共振渗透率PF 流体电阻率测井PI 微球聚焦屏流比PIH 油气有效渗透率PIW 水的有效渗透率POR 孔隙度Por / Ф孔隙度PORB 储层的孔隙度PORb Pore / Фe有效孔隙度PORG 气指数PORT 总孔隙度Port / Фt总孔隙度PORW 含水孔隙度POTA 钾POTV １００％粘土中钾的体积PPOR 核磁T2谱PPORB 核磁T2谱PPORC 核磁T2谱PR 泊松比PRESS URE 压力QA 加速计质量QB 磁力计质量QRTT 反射波采集质量QV 阳离子交换容量R04 0.4米电位电阻率R045 0.45米电位电阻率R05 0.5米电位电阻率R1 1米底部梯度电阻率R25 2.5米底部梯度电阻率R250 2.5米底部梯度电阻率R4 4米底部梯度电阻率R400 4米底部梯度电阻率R4AT 200兆赫兹幅度比R4AT_1 47兆赫兹幅度比R4SL 200兆赫兹电阻率R4SL_1 47兆赫兹电阻率R6 6米底部梯度电阻率R8 8米底部梯度电阻率RAD1 井径（极板半径）RAD2 井径（极板半径）RAD3 井径（极板半径）RAD4 井径（极板半径）RAD5 井径（极板半径）RAD6 井径（极板半径）RADS 井径（极板半径）RATI 地层比值RB 相对方位RB_1 相对方位角RBOF 相对方位RD 深双侧向电阻率测井RFOC 八侧向电阻率RHOB 岩性体积密度RHOM 岩性密度RILD 深感应电阻率RILM 中感应电阻率RLML 微梯度电阻率Rm 泥浆电阻率Rmf 泥浆滤液电阻率RMG 微梯度电阻率RMLL 微侧向电阻率测井RMN 微电位电阻率RMSF 微球型聚焦电阻率RNML 微电位电阻率ROT 相对方位RPRX 邻近侧向电阻率RS 浅双侧向电阻率测井Rt 地层真电阻率Rw 地层水电阻率Rxo 冲洗带地层电阻率RXO1 RXO1微球形聚焦电阻率SDBI 特征值增益SFL 球型聚焦电阻率SFLU 球型聚焦电阻率SGAT 采样时间SGR 无铀伽马SH 微电位电阻率SICA 硅钙比SIG 井周成像特征值SIGC 俘获截面SIGC2 示踪俘获截面SMOD 横波模量SNL 井壁中子SNP 井壁中子孔隙度测井SNUM 特征值数量So 含油饱和度Sor 残余油饱和度SP 自然电位SPER 特征值周期Sw 含水饱和度SWB 束缚水饱和度Swirr / SIRR 束缚水饱和度SWN 井壁中子测井Swxo 冲洗带含水饱和度T2 核磁T2谱T2-BIN-A 核磁共振区间孔隙度T2-BIN-B 核磁共振区间孔隙度T2-BIN-PR 核磁共振区间孔隙度T2GM T2分布对数平均值T2LM T2分布对数平均值TCHK 绿泥石和高岭石含量TEMP 井温TENS 张力TH 钍THOR 钍TILL 伊利石含量TKRA 钍钾比TPI 钍钾乘积指数TPOR 核磁共振总孔隙度TRIG 模式标志TS 横波时差TT1 上发射上接受的传播时间TT2 上发射下接受的传播时间TT3 下发射上接受的传播时间TT4 下发射下接受的传播时间TURA 钍铀比U 铀UKRA 铀钾比ULSEL 超长电极距测井URAN 铀VAMP 扇区水泥图VDL 声波变密度VMVM 核磁共振自由流体体积VPVS 纵横波速度比Vsh / Sh 泥质含量VWF 可视波形WAV1 第一扇区的波列WAV2 第二扇区的波列WAV3 第三扇区的波列WAV4 第四扇区的波列WAV5 第五扇区的波列WAV6 第六扇区的波列WAVE 变密度图WF 全波列波形ZCORR 密度校正值三条泥质指示曲线：自然电位（SP）、自然伽马（GR）、井径（CAL）三条电阻率曲线：深、中、浅电阻率（一般是组合的，如双侧向－微球，双感应－八侧向等）三条孔隙度曲线：声波（AC）、密度（DEN）、中子（CNL或SNP）这是裸眼测井最基本的系列，可以解决储层划分、孔隙度计算、油气层识别（饱和度计算）等基本问题。