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| obsolescence notice this product is obsolete. this information is available for your convenience only. for more information on zarlink?s obsolete products and replacement product lists, please visit http://products.zarlink.com/obsolete_products/
8-73 features ? dual channel full duplex transcoder ? 32 kbit/s and 24 kbit/s adpcm coding, ? compatible to g.721 & and g.723 (1988) and ansi t1.303-1989 ? low power operation, total 25mw typical ? asynchronous 4.096 mhz master clock operation ? transparent adpcm bypass capability ? serial interface for both pcm and adpcm data streams ? st-bus interface supported ? pin selected m -law or a-law operation ? pin selected ccitt or sign-magnitude pcm coding ? single 5 volt power supply ? optional reset value (ccitt table 3/g.721) capability applications ? pair gain ? voice mail systems ? wireless set base stations description the dual-channel adpcm transcoder is a low power, cmos device capable of two encoder functions and two decoder functions. two 64 kbit/s pcm channels are compressed into two 32 kbit/s adpcm channels, and two 32 kbit/s adpcm channels are expanded into two 64 kbit/s pcm channels. the 32 kbit/s adpcm transcoding algorithm utilized conforms to ccitt recom- mendation g.721 and ansi t1.303-1989. the device also supports a 24 kbit/s (three bit word) algorithm (ccitt/g.723). switching, on-the-?y, between 32 kbit/s and 24 kbit/ s, is possible by toggling the appropriate mode select (ms1-ms4) control pins. ordering information MT9125ae 24 pin plastic dip (600 mil) MT9125ap 28 pin plcc -40 to +85 c figure 1 - functional block diagram timing st-bus converter adpcm i/o transcoder 1 transcoder 2 pcm i/o control decode en1 en2 dsto dsti enb1 enb2 vdd vss pwrdn ic ms1 ms2 a/ m format ms3 ms4 c2o bclk f0i mclk ens adpcmi adpcmo ena issue 3 august 1993 MT9125 dual adpcm transcoder preliminary information cmos MT9125 preliminary information 8-74 figure 2 - pin connections pin description pin # name description dip plcc 1 2 mclk master clock input. this 4.096 mhz clock is used as an internal master clock and must be provided during both st-bus and ssi modes of operation. this is a ttl level input. in st-bus mode the mclk input (also known as c4i in st-bus terms) is derived from the synchronous 4.096 mhz clock available from the layer 1 transceiver device. the c4i clock, input to mclk, is used in this mode as both the internal master clock and for deriving the c2o output clock and en1/en2 output enable strobes. in ssi mode a 4.096 mhz master clock must be derived from an external source. this master clock may be asynchronous relative to the 8 khz frame reference. 23 f0i frame alignment input pulse for st-bus interface operation. this input should be tied low if st-bus operation is not required. this is a ttl level input. 3 4 c2o 2.048mhz clock output for st-bus applications. this clock is mclk divided by 2 and inverted. the c2o output activity state is governed by the f0i input pin condition. f0i input c2o output v ss disabled (ssi mode automatically activated) v dd enabled active f0i strobe enabled and aligned to f0i due to c4i input at mclk 4 5 dsto serial pcm octet output stream. refer to the serial timing diagram of figure 12. 5 6 dsti serial pcm octet input data stream. refer to the serial timing diagram of figure 12. this is a ttl level input. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 24 23 22 21 20 19 18 17 mclk f0i c2o dsto dsti bclk vss enb2 enb1 ms1 ms2 ms3 ens en2 en1 adpcmo adpcmi ena vdd ic pwrdn format a/ m ms4 28 pin plcc 4 5 6 7 8 9 10 11 25 24 23 22 21 20 19 c2o adpcmo adpcmi ena vdd nc ic pwrdn dsto dsti bclk vss nc enb2 enb1 24 pin pdip a/ m 3 2 1 28 27 26 12 13 14 15 16 17 18 f0i mclk nc ens en2 en1 ms1 ms2 ms3 nc ms4 format preliminary information MT9125 8-75 6 7 bclk bit clock input for both pcm and adpcm ports; used in ssi mode only. the falling edge of this clock is used to clock data in on dsti and adpcmi. the rising edge is used to clock data out on dsto and adpcmo. can be any rate between 128 khz and 2.048 mhz. refer to the serial timing diagrams of figures 12 and 13. when not used, this pin should be tied to v ss . this is a ttl level input. 78 v ss power supply ground (0 volts). 8 10 enb2 enable strobe input for b2 channel pcm timing in ssi mode only. a valid 8-bit strobe must be present at this input if there are no st-bus signals at f0i and mclk. when the device detects a valid frame pulse at f0i, pcm timing for the b2 st-bus channel is decoded internally and the enb2 input is ignored. when not used this pin should be tied to v ss . this is a ttl level input. 9 11 enb1 enable strobe input for b1 channel pcm timing in ssi mode only. a valid 8-bit strobe must be present at this input if there are no st-bus signals at f0i and mclk. when the device detects a valid frame pulse at f0i, pcm timing for the b1 st-bus channel is decoded internally and the enb1 input is ignored. when not used this pin should be tied to v ss . this is a ttl level input. 10, 11 12, 13 ms1, ms2 mode select control input pins 1 and 2 for the b1 channel according to the following: ms2 ms1 b1 channel 0 0 algorithm reset 0 1 adpcm bypass mode (24 or 32 kbit/s) 1 0 24 kbit/s adpcm mode 1 1 32 kbit/s adpcm mode these are ttl level inputs. 12, 13 14, 16 ms3, ms4 mode select control input pins 3 and 4 for the b2 channel according to the following: ms4 ms3 b2 channel 0 0 algorithm reset 0 1 adpcm bypass mode (24 or 32 kbit/s) 1 0 24 kbit/s adpcm mode 1 1 32 kbit/s adpcm mode these are ttl level inputs. 14 17 a/ m law select input. selects m -law when low, a-law when high. this is a ttl level input. 15 18 format format select input. selects ccitt pcm coding if high, or sign magnitude pcm if low. this is a ttl level input. 16 19 pwrdn power down input. logic low on this pin forces the device to assume an internal power down mode where all operation is halted. this mode minimizes power consumption. outputs are tri-stated. this is a schmidt trigger input. 17 20 ic internal connection. tie to v ss for normal operation. 18 22 v dd positive power supply input, 5 volts 10%. 19 23 ena enable strobe input for both input and output adpcm channels; used for ssi operation only. refer to figure 3. when not used, tie to vss. this is a ttl level input. 20 24 adpcmi serial adpcm word input data stream. refer to the serial timing diagram of fig. 13. this is a ttl level input. 21 25 adpcmo serial adpcm word output stream. refer to the serial timing diagram of fig.13. pin description (continued) pin # name description dip plcc MT9125 preliminary information 8-76 22 26 en1 channel 1 output enable strobe. this output is decoded from the st-bus c4i and f0i signals and its position, within the st-bus stream, may be controlled via the ens pin. refer to the st-bus relative timing diagram shown in figure 4. 23 27 en2 channel 2 output enable strobe. this output is decoded from the st-bus c4i and f0i signals and its position, within the st-bus stream, may be controlled via the ens pin. refer to the st-bus timing diagram shown in figure 4. 24 28 ens enable select input for st-bus operation only. this control pin changes the st-bus channel position of en1 and en2 as well as the adpcm channel position. refer to the st- bus timing diagram shown in figure 4. when not used this pin should be tied to v dd . this is a ttl level input. 1, 9, 15, 21 nc no connection. leave open circuit. pin description (continued) pin # name description dip plcc functional description the dual-channel adpcm transcoder is a low power, cmos device capable of two encoder functions and two decoder functions. two 64 kbit/s pcm channels (pcm octets) are compressed into two 32 kbit/s adpcm channels (adpcm words), and two 32 kbit/s adpcm channels (adpcm words) are expanded into two 64 kbit/s pcm channels (pcm octets). the adpcm transcoding algorithm utilized conforms to ccitt recommendation g.721 and ansi t1.303-1989. the device also supports a 24 kbit/s (three bit word) algorithm (ccitt/g.723). switching, on-the-?y, between 32 kbit/s and 24 kbit/s is possible by toggling the appropriate mode select (ms1-ms4) control pins. the internal circuitry requires very little power to operate; 25mw typically for dual channel operation. a master clock frequency of 4.096 mhz is required for the circuit to complete two encode channels and two decode channels. operation with an asynchronous master clock, relative to the 8 khz reference, is allowed. all optional functions of the device are pin selected, no microprocessor is required. this allows a simple interface with industry standard codecs, dual codecs, digital phone devices, and layer 1 transceivers. the pcm and adpcm serial busses are a synchronous serial interface (ssi), allowing serial clock rates from 128 khz to 2.048 mhz. additional pins on the device allow an easy interface to an st- bus component. on chip channel counters provide channel enable outputs, as well as a 2.048 mhz clock output, useful for driving the timing input pins of standard codec devices. serial i/o ports (adpcmi, adpcmo, ena, enb1, enb2, dsti, dsto, c2o, en1, en2, ens, f0i) serial i/o data transfer to the dual adpcm transcoder is provided through the pcm and the adpcm ports. serial i/o port operation is similar for both st-bus and ssi modes. the dual adpcm transcoder determines the mode of operation by monitoring the signal applied to the f0i pin. when a valid st-bus frame pulse (244ns low going pulse) is connected to the f0i pin the transcoder will assume st-bus operation. if f0i is tied continuously to v ss the transcoder will assume ssi operation. pin functionality in each of these modes is described in the following sub-sections. adpcm p or t oper ation (adpcmi, adpcmo , ena) the adpcm port consists of adpcmi, adpcmo and ena. adpcm port functionality is similar for both st- bus and ssi operation, the difference being in where the bclk signal is derived and in where the adpcm words are placed within the 8 khz frame. for ssi operation (i.e., when f0i is tied continuously to v ss ) both channels of adpcm code words are transferred over adpcmi/adpcmo at the bit clock rate (bclk) during the channel time de?ned by the input strobe at ena. refer to figure 3 and to figure 13. data is latched into the adpcmi pin with the falling edge of bclk while output data is made available at adpcmo on the rising edge of bclk. preliminary information MT9125 8-77 for st-bus operation (i.e., when a valid st-bus frame pulse is applied to the f0i input) the bit rate, at 2.048 mhz, is generated internally from the master clock input at the mclk pin. the bclk and ena inputs are ignored. data is latched into the adpcmi pin at the three-quarter bit position which occurs at the second rising edge of mclk ( c4i) within the bit cell boundary. output data, on adpcmo, is made available at the ?rst falling edge of mclk ( c4i) within the bit cell boundary. refer to figure 13. adpcm word placement, within the st-bus frame, is governed by the logic state applied at the ens input pin. referring to figure 4, when ens = 0, the adpcm words are placed in channel 2 while when ens = 1 the adpcm words are placed in channel 3. unlike the pcm octets the adpcm words never reside within the st-bus channel 0 or 1 timeslots. pcm p or t oper ation (dsti, dst o , enb1, enb2) the pcm port consists of dsti, dsto, enb1 and enb2. pcm port functionality is almost identical for both st-bus and ssi operation, the difference being from where the bclk signal is derived and whether the enable strobes are generated internally or sourced externally. both channels of pcm octets are transferred over dsti/dsto at the bit clock rate during the channel time de?ned by the input strobes at enb1 and enb2 or by internally generated timeslots. for st-bus operation, (i.e., when a valid st-bus frame pulse is applied to the f0i input) the bit rate, at 2.048 mhz, is generated internally from the master clock input at the mclk pin. the bclk and ena inputs are ignored. st-bus timeslot assignment is also generated internally and can be programmed into channels 0 and 1 or into channels 2 and 3 with the ens input pin. refer to figure 4. in this mode the enb1 and enb2 inputs are ignored by the device. the decoded channel timeslots (0 and 1 or 2 and 3) are made available, along with the 2.048 mhz bit clock, at en1, en2 and c2o for controlling codec devices as shown in the applications section (refer to figures 7 and 11). data is latched into the dsti pin at the three-quarter bit position which occurs at the second rising edge of mclk ( c4i) within the bit cell boundary. output data, on dsto, is made available at the ?rst falling edge of mclk ( c4i) within the bit cell boundary. refer to figure 12. for ssi operation, (i.e., when f0i is tied continuously to v ss ) the bit rate is set by the input clock presented at the bclk pin. data is transferred at the bit clock rate (bclk) during the b1 and b2 channels as de?ned by input strobes enb1 and enb2, respectively. note that enb1 and enb2 are also used as the framing inputs for internal operation of figure 3 - ssi mode relative timing enb1 enb2 dsti/o ena adpcmi/o 8 bits 8 bits b1 channel b2 channel 4 bits b1 b2 b1 b2 4 bits 4 bits 4 bits normally ena is derived from the same strobes which drive the enb1 or enb2 inputs. however, as long as ena is eight cycles of bclk length, it may be positioned anywhere within the 8 khz frame. MT9125 preliminary information 8-78 figure 4 - st-bus mode relative timing f0i dsti/o en1 en2 adpcmi/o en1 en2 adpcmi/o channel 0 channel 1 channel 2 channel 3 b1 b2 b1 b2 b1 b2 b1 b2 ens=0 ens=1 in st-bus mode the ena, enb1 and enb2 input strobes are ignored. all timing is dervied internally from the f0i, mclk and ens inputs. the device and must, therefore, be present whenever a transcoding operation is required. these inputs may be tied together and connected to the same strobe for single channel operation. only the b1 nibble is valid in this mode. data is latched into the dsti pin with the falling edge of the bit clock while output data is made available at dsto on the rising edge of the bit clock. st -b us con v ersion ( f0i , c2o , en1, en2, ens) a simple converter circuit is incorporated which allows st-bus signals to be converted to ssi signals. in this manner it is very simple for an st- bus application to be mixed with codecs utilizing a strobed data i/o. this converter circuit consists of the f0i input and c2o, en1 and en2 output pins (as well as the mclk input master clock). the output c4b clock and frame pulse strobe ( f0b), from the st-bus layer 1 transceiver, are connected directly to the master clock (mclk) and frame pulse ( f0i) inputs of the transcoder. a 2.048 mhz (c2o) bit clock output is made available when a valid frame pulse is connected to the f0i pin or the f0i pin is tied high. if the f0i pin is tied low the c2o output is forced continuously to a logic low level (not tri-stated). forcing the c2o output to logic low enhances power conservation as well as removing a non-required clock signal from the circuit. this 2.048 mhz bit clock may be used to control external codec functions. the 4.096 mhz and frame pulse signals are also decoded into two output strobes corresponding to the b1 and b2 channel timeslots of the st-bus. these strobes (en1 and en2) are then used to control the timing inputs of an external codec. a typical example of this connection scheme is shown in the application diagram of figure 7. the enable strobe pin (ens) is used to position the output strobes en1 and en2 within the st-bus frame. referring to figure 4, when ens=0 the output strobes are positioned in channels 0 and 1 of the st- bus frame. when ens=1 the output strobes are positioned in channels 2 and 3 of the st-bus frame. this ?exibility allows the transcoder to be used in st- bus basic rate applications where channels 0 and 1 are de?ned as the d and c channels, respectively, and also in line-card applications where the full 2.048 mhz bandwidth is used for conveying data and/or digitally encoded voice information. preliminary information MT9125 8-79 mode selection (ms1, ms2, ms3, ms4) separate mode select pins are available for per- channel b1 and b2 operation. ms1 and ms2 are used to con?gure the b1 channel while ms3 and ms4 con?gure the b2 channel. normally the mode select pins are operated as static control lines. the exception to this is for on-the-?y programming to/ from 32 kbit/s from/to 24 kbit/s modes. algorithm reset mode an algorithm reset is accomplished by forcing all mode select pins simultaneously to logic zero. while asserted, this will cause the device to incrementally converge the internal variables of both channels to the 'optional reset values' per g.721. invoking the reset conditon on only one channel will cause that channel to be reset properly and the other channels operation to be unde?ned. this optional reset requires that the master clock (mclk) and frame pulse (enb1/2 or f0i) remain active and that the reset condition be valid for at least four frames. note that this is not a power down mode. adpcm by-pass mode in adpcm bypass mode the b1 and b2 channel words are transparently relayed (with a two-frame delay) to/from the adpcm port and placed into the most signi?cant nibbles of the b1 and b2 channel pcm octets. refer to figure 5. the ability to transfer adpcm words transparently through the transcoder enables set-to-set connections for wireless telephony applications. 24 kbit/s mode in 24 kbit/s mode (ccitt g.723) pcm octets are transcoded into three bit words rather than the four bit words of the standard 32 kbit/s adpcm. this is useful in situations where lower bandwidth transmission is required. dynamic operation of the mode select control pins will allow switching from 32 kbit/s mode to 24 kbit/s mode on a frame by frame basis. figure 6 shows the internal pipelining of the conversion sequence and how the mode select pins are to be used. fig. 15 details the timing figure 5 - adpcm by-pass mode requirements necessary for on-the-?y control of the mode select pins. the 3-bit adpcm words occupy the most signi?cant bit positions of the standard 4-bit adpcm word. 32 kbit/s adpcm mode in 32 kbit/s mode pcm octets are transcoded into four bit words as described in ccitt g.721. this is the standard mode of operation and, if the other modes are not required, can be implemented by simply tying the per-channel mode select pins to v dd . master clock (mclk) a 4.096 mhz master clock is required for execution of the dual transcoding algorithm. the algorithm requires 512 cycles of mclk during one frame for proper operation. this input, at the mclk pin, may be asynchronous with the 8 khz frame provided that the lowest frequency, and/or deviation due to clock jitter, still meets the minimum strobe period requirement of 512 t c4p -50nsec. (see ac electrical characteristics - serial pcm/adpcm interfaces.) for example, a system producing large jitter values can be accommodated by running an over-speed mclk to ensure that a minimum 512 mclk cycles per frame is obtained. the minimum mclk period is 190 nseconds, which translates to a maximum frequency of 5.26 mhz. extra mclk cycles (>512/ frame) are acceptable because the transcoder is re- aligned by the appropriate strobe signals each frame. b1 channel b2 channel ms2 ms1 oper ational mode ms4 ms3 0 0 1 1 0 1 0 1 algorithm reset adpcm bypass mode (24 or 32 kbit/s) 24 kbit/s adpcm mode 32 kbit/s adpcm mode 0 0 1 1 0 1 0 1 adpcmi adpcmo dsto dsti dual adpcm transcoder b1 b2 b1 b2 3 2 1 0 x x x x x x x x 3 2 1 0 3 2 1 0 3 2 1 0 in adpcm by-pass mode, the b1 and b2 channel adpcm words are transparently passed (with a two frame delay) to the most significant nibbles of the pcm octets. this feature allows two voice terminals, which utilize adpcm transcod- ing, to communicate through a system (i.e., pbx, key-system) without incurring unnecessary transcode conversions. this arrangement also allows byte-wide or nibble-wide transport through a switching matrix. adpcm i/o dsti/o MT9125 preliminary information 8-80 figure 6 - pipelining for dynamic 32/24 kb/s operation dsti adpcmo ena enb1 or en1 ms1/3 ms2/4 frame n-1 frame n frame n+1 pcm byte "x" latched into device during frame n-1 pcm byte "x" processed according to msn input states latched during frame n adpcm word "x" output from device during frame n+1 1,1=32 kb/s 1,0=24 kb/s 1,1=32 kb/s this diagram shows the conversion sequence from pcm to adpcm. the same pipelining occurs in the reverse adpcm to pcm direction. total delay from data input to data output = 2 frames. see figure 15 for detailed enb1/en1 timing. bit clock (bclk) for ssi operation the bit rate, for both adpcm and pcm ports, is determined by the clock input at bclk. bclk must be eight periods in duration and synchronous with the 8 khz frame input at enb1. data is sampled at dsti and at adpcmi concurrent with the falling edge of bclk. data is available at dsto and adpcmo concurrent with the rising edge of bclk. bclk may be any rate between 128 khz and 2.048 mhz. refer to figures 12 and 13. for st-bus operation bclk is ignored and the bit rate is internally set to 2.048 mhz. pcm law control (a/ m , format) the pcm companding/coding law invoked by the transcoder is controlled via the a/ m and format pins. ccitt g.711 companding curves, m -law and a-law, are determined by the a/ m pin (0= m - law; 1=a-law). per sample, digital code assignment can conform to ccitt g.711 (when format=1) or to sign-magnitude coding (when format=0). table 1 illustrates these choices. table 1 processing delay through the device one 8 khz frame is required for serial loading of the input buffers, and one frame is required for processing, for a total of two frame delays through the device. all internal input/output pcm and adpcm shift registers are parallel loaded through secondary buffers on an internal frame pulse. the device derives its internal frame reference from the f0i, enb1 and enb2 pins in the following manner. if a valid st-bus frame pulse is present at the f0i pin the transcoder will assume st-bus operation and will use this input as the frame reference. in this format 01 pcm code sign- magnitude a/ m = 0 or 1 ccitt (g.711) (a/ m = 0) (a/ m = 1) + full scale 1111 1111 1000 0000 1010 1010 + zero 1000 0000 1111 1111 1101 0101 - zero 0000 0000 0111 1111 0101 0101 - full scale 0111 1111 0000 0000 0010 1010 preliminary information MT9125 8-81 figure 7 - pair gain application (st-bus/ssi) figure 8 - pair gain application (st-bus/st-bus) t r t r t r t r t r mt8910 MT9125 l in + l in - l out + l out - f0b c4b dsto dsti fpi c4i dsti dsto gate array ring generator to slics hookswitch from slics c2o bclk f0i mclk adpcmi adpcmo ena ens en1 en2 dsti dsto enb1 enb2 MT9125 c2o bclk f0i mclk adpcmi adpcmo ena ens en1 en2 dsti dsto enb1 enb2 v dd d x d r fs x fs r bclk x mclk x v fxl- v fro v fxl+ d x d r fs x fs r bclk x mclk x v fxl- v fro v fxl+ d x d r fs x fs r bclk x mclk x v fxl- v fro v fxl+ d x d r fs x fs r bclk x mclk x v fxl- v fro v fxl+ s l i c s l i c s l i c s l i c mt8910 l in + l in - l out + l out - f0b c4b dsto dsti fpi c4i dsti dsto gate array ring generator to slics hookswitch from slics MT9125 c2o bclk f0i mclk adpcmi adpcmo ena ens en1 en2 dsti dsto enb1 enb2 MT9125 c2o bclk f0i mclk adpcmi adpcmo ena ens en1 en2 dsti dsto enb1 enb2 v dd t r dout din stb1 clk ain+ ain- aout dual codec dout din stb1 clk ain+ ain- aout dual codec 2 x s l i c t r t r t r t r 2 x s l i c MT9125 preliminary information 8-82 con?guration the enb1 and enb2 inputs are ignored. if f0i is tied continuously to v ss , then ssi operation will be assumed and the transcoder will use the strobes connected to enb1 and enb2 as its internal reference. power-down operation ( pwrdn) to minimize power consumption a pin selected, power-down option is provided. device power down is accomplished by forcing the pwrdn pin to v ss . this asynchronous control forces all internal clocking to halt and the c2o, en1, en2, dsto and adpcmo outputs to become tri-stated. upon returning pwrdn to v dd coincident with the next alignment signal, all outputs will return to their active state and the internal clocks are re-started. in this mode the adpcm algorithm is not reset to the 'optional reset values', however, the self-convergent nature of the algorithm will ensure that convergence of the (ad)pcm streams will occur within 3496 frames as speci?ed by ccitt g.721. removal of the bclk and mclk inputs is not necessary during power-down mode. if the device is released from power-down without a valid mclk the adpcmo and pcmo outputs will become active, driving either continuous logic high or logic low, until a mclk signal is applied to resume internal operation. pwrdn is a schmidt trigger input. applications various con?gurations of pair gain drops are depicted in figures 7, 8 and 9. these show applications using mixed st-bus/ssi, all st-bus and all ssi implementations. figure10 shows an st- bus line card application for pair gain while figure 11 shows a 2-channel, wireless-set, base station application based upon st-bus. figure 9 - pair gain application (ssi/ssi) t r t r t r t r d x d r fs x fs r bclk x mclk x v fxl- v fro v fxl+ d x d r fs x fs r bclk x mclk x v fxl- v fro v fxl+ d x d r fs x fs r bclk x mclk x v fxl- v fro v fxl+ d x d r fs x fs r bclk x mclk x v fxl- v fro v fxl+ gate array ring generator to slics hookswitch from slics t r l in + l in - l out + l out - bclk mclk tx rx en1 en2 MT9125 bclk f0i mclk adpcmi adpcmo ena ens dsti dsto enb1 enb2 v dd MT9125 bclk f0i mclk adpcmi adpcmo ena ens dsti dsto enb1 enb2 v dd s l i c s l i c s l i c s l i c preliminary information MT9125 8-83 figure 10 - application (st-bus line card) figure 11 - application (2-channel, wireless-set, base station) MT9125 c2o bclk f0i mclk adpcmi adpcmo ena ens en1 en2 dsti dsto enb1 enb2 MT9125 c2o bclk f0i mclk adpcmi adpcmo ena ens en1 en2 dsti dsto enb1 enb2 l in + l in - l out + l out - f0b c4b dsto dsti fpob fpb system frame pulse or delayed frame pulse from previous selection mt8980 c & d channel switch 1/2 bandwidth unusable mt8980 b channel switch fpib dsti dsto c4ib fpib dsto dsti c4ib fpob fpib dsto dsti c4ib fpob fpib dsto dsti c4ib fpob 1 7 8 c4ib mt8910 dsti dsto v dd t r t r mt89xx l in l in l out l out f0b c4b dsto dsti MT9125 c2o bclk f0i mclk adpcmi adpcmo ena ens en1 en2 dsti dsto enb1 enb2 v dd bit clock adpcm enable rfb1 rfb2 2 channel rf section the layer 1 device shown may be the 2-wire mt8910 or mt8972 or the 4-wire mt8930. b1 b2 b0 b1 b2 b3 b4 b5 b6 b7 x b0 b1 b2 b3 b0 b1 b2 b3 b0 b1 b2 b3 b0 b1 b2 b3 b0 b1 b2 b3 b1 b2 b2 b1 b4 b5 b6 b7 x x x x x x x enb1 (and ena) enb2 adpcm nibbles concatenated into one 8 bit timeslot normal st-bus channel assignment in adpcm by-pass mode (ms pin control) the adpcm nibbles are automatically inserted into the most significant nibbles of the 8-bit dsti/o b1 and b2 bytes. MT9125 preliminary information 8-84 * exceeding these values may cause permanent damage. functional operation under these conditions is not implied. ? typical ?gures are at 25 c and are for design aid only: not guaranteed and not subject to production testing. ? typical ?gures are at 25 c and are for design aid only: not guaranteed and not subject to production testing. absolute maximum ratings* parameter symbol min max units 1 supply voltage v dd -v ss -0.3 7.0 v 2 voltage on any i/o pin v i | v o -0.3 v dd + 0.3 v 3 continuous current on any i/o pin i i | i o 20 ma 4 storage temperature t st -65 150 c 5 power dissipation p d 500 mw 6 latch-up immunity i lu 100 ma recommended operating conditions - voltages are with respect to ground (v ss ) unless otherwise stated. characteristics sym min typ ? max units test conditions 1 supply voltage v dd 4.5 5.0 5.5 v 2 input high voltage v ih 2.4 v dd v 400mv noise margin 3 input low voltage v il 0 0.4 v 400mv noise margin 4 operating temperature t a -40 85 c dc electrical characteristics - voltages are with respect to ground (v ss ) unless otherwise stated. characteristics sym min typ ? max units test conditions 1 supply current static operating i cc i dd1 100 5 m a ma pwrdn = 0 pwrdn = 1, clocks active 2 high level input voltage v ih 2.0 v all inputs except pwrdn 3 low level input voltage v il 0.8 v all inputs except pwrdn 4 input leakage current i ih /i il 0.1 10 m av dd =5.5v, v in =v ss to v dd 5 high level output voltage v oh 2.4 v 6 low level output voltage v ol 0.4 v 7 output low (sink) current i ol 4.0 15 ma v ol =0.4v, v dd =4.5v 8 output high (source) current i oh 4.0 10 ma v oh =2.4v, v dd =4.5v 9 high impedance leakage i oz 110 m av dd =5.5v, v in =v ss to v dd 10 output capacitance c o 10 pf 11 input capacitance c i 15 pf 12 positive going threshold voltage ( pwrdn only) hysteresis negative going threshold voltage ( pwrdn only) v+ v + -v - v - 3.7 1.0 1.3 v v v preliminary information MT9125 8-85 ? timing is over recommended temperature & power supply voltages. ? typical ?gures are at 25 c and are for design aid only: not guaranteed and not subject to production testing. ac electrical characteristics ? - serial pcm/adpcm interfaces (see figures 12 & 13) voltages are with respect to ground (v ss ) unless otherwise stated. characteristics sym min typ ? max units test conditions 1 data clock high t clh 160 ns c l =150pf 2 data clock low t cll 160 ns c l =150pf 3 bclk period t bcl 400 7900 ns c l =150pf 4 data output delay (excluding ?rst bit) t dd 60 ns c l =150pf 5 output active to high z t ahz 60 ns c l =150pf 6 strobe signal setup t sss 80 t bcl - 80 ns c l =150pf 7 strobe signal hold t ssh 80 t bcl - 80 ns c l =150pf 8 strobe period relative to mclk (enb1, enb2, ena) 512t c4p - 50 ns c l =150pf 9 data input setup t dis 50 ns c l =150pf 10 data input hold t dih 50 ns c l =150pf 11 strobe to data delay (?rst bit) t sd 60 ns c l =150pf 12 f0i setup t f0is 50 122 150 ns c l =150pf 13 f0i hold t f0ih 50 122 150 ns c l =150pf 14 mclk ( c4i) duty cycle t h /t l x100 40 50 60 % c l =150pf 15 mclk ( c4i) period t c4p 190 244.2 ns c l =150pf 16 data output delay t dstod 125 ns c l =150pf 17 data in hold time t dstih 50 ns c l =150pf 18 data in setup time t dstis 50 ns c l =150pf MT9125 preliminary information 8-86 figure 12- serial pcm port timing figure 13 - serial adpcm port timing bclk enb1 or enb2 dsti dsto mclk f0i s s i s t - b u s t bcl t clh t cll t sss t ssh b7 b6 b5 b1 b0 t dis t dih t dstis t dstih t dd t ahz t dstod t h t f0ih t l t c4p t f0is b7 b6 b5 b1 b0 v ih v il v ih v il v il v il v oh v ol v ih v il v ih v il t sd v ih v il v ih v il v il v il v oh v ol v ih v il v ih v il t ssh b2-3 b2-4 t dd t ahz t dstod t c4p b2-3 b2-4 t bcl t clh t cll t sss b1-1 b1-2 b1-3 t dis t dih t dstis t dstih b1-1 b1-2 b1-3 t h t f0ih t l t f0is bclk ena adpcmi adpcmo mclk f0i s s i s t - b u s t sd preliminary information MT9125 8-87 ? timing is over recommended temperature & power supply voltages. ? typical ?gures are at 25 c and are for design aid only: not guaranteed and not subject to production testing. figure 14 - st-bus timing for external signal generation ? timing is over recommended temperature & power supply voltages. ? typical ?gures are at 25 c and are for design aid only: not guaranteed and not subject to production testing. figure 15 - mode select set-up and hold timing for dynamic operation ac electrical characteristics ? - st-bus conversion (see figure 14) voltages are with respect to ground (v ss ) unless otherwise stated. characteristics sym min typ ? max units test conditions 1 delay mclk falling to c2o rising t d1 100 ns 150pf load 2 delay mclk falling to enable t d2 100 ns 150pf load ac electrical characteristics ? - mode select timing (see figure 15) voltages are with respect to ground (v ss ) unless otherwise stated. characteristics sym min typ ? max units test conditions 1 mode select setup t su 500 ns 2 mode select hold t hold 500 ns f0i mclk ( c4i) c2o en1 en2 t d1 t d2 t d2 v ih v il v il v il v oh v ol v oh v ol ms1-ms4 enb1 (ssi mode) en1 (st-bus mode) t su t hold MT9125 preliminary information 8-88 notes: www.zarlink.com information relating to products and services furnished herein by zarlink semiconductor inc. or its subsidiaries (collectively ?zarlink?) is believed to be reliable. however, zarlink assumes no liability for errors that may appear in this publication, or for liability otherwise arising from t he application or use of any such information, product or service or for any infringement of patents or other intellectual property rights owned by third parties which may result from such application or use. neither the supply of such information or purchase of product or service conveys any license, either express or implied, u nder patents or other intellectual property rights owned by zarlink or licensed from third parties by zarlink, whatsoever. purchasers of products are also hereby notified that the use of product in certain ways or in combination with zarlink, or non-zarlink furnished goods or services may infringe patents or other intellect ual property rights owned by zarlink. this publication is issued to provide information only and (unless agreed by zarlink in writing) may not be used, applied or re produced for any purpose nor form part of any order or contract nor to be regarded as a representation relating to the products or services concerned. the products, t heir specifications, services and other information appearing in this publication are subject to change by zarlink without notice. no warranty or guarantee express or implied is made regarding the capability, performance or suitability of any product or service. information concerning possible methods of use is provided as a guide only and does not constitute any guarantee that such methods of use will be satisfactory in a specific piece of equipment. it is the user?s responsibility t o fully determine the performance and suitability of any equipment using such information and to ensure that any publication or data used is up to date and has not b een superseded. manufacturing does not necessarily include testing of all functions or parameters. these products are not suitable for use in any medical products whose failure to perform may result in significant injury or death to the user. all products and materials are sold and services provided subject to zarlink?s conditi ons of sale which are available on request. purchase of zarlink?s i 2 c components conveys a licence under the philips i 2 c patent rights to use these components in and i 2 c system, provided that the system conforms to the i 2 c standard specification as defined by philips. zarlink, zl and the zarlink semiconductor logo are trademarks of zarlink semiconductor inc. copyright zarlink semiconductor inc. all rights reserved. technical documentation - not for resale for more information about all zarlink products visit our web site at |
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