AMD Am79C930 Bedienungsanleitung
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Die Gebrauchsanleitung AMD Am79C930 sollte vor allem folgendes enthalten:
- Informationen über technische Daten des Geräts AMD Am79C930
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In der Gebrauchsanleitung finden wir vor allem die Antwort über den Bau sowie die Möglichkeiten des Geräts AMD Am79C930, über die Nutzung bestimmter Accessoires und eine Reihe von Informationen, die erlauben, jegliche Funktionen und Bequemlichkeiten zu nutzen.
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Inhaltsverzeichnis der Gebrauchsanleitungen
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Seite 1
PRELIMINARY This document contains in f o r mation on a product under d e v elopment at Ad v anced Micro D e vice s . The in f o r mation is intended to help y ou e v aluate this product . AMD rese r v es the r ight to change or discontinue wo r k on this proposed product without notic e . Pu b lication# 20183 R e v : B Amendment/ 0 Issue Date : Ap[...]
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Seite 2
2 Am79C930 PRELIMINARY ORDERING INFORM A TION Standa r d P r oducts AMD standard products are a v aila b le in s e v e r al pa c kages and operating r ange s . The order number ( v alid combination) is f o r med b y a combination of the elements bel o w . V alid Combinations V alid combinations list configurations planned to be sup- po r ted in v [...]
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Seite 3
Am79C930 3 PRELIMINARY BLOCK DI A GRAM PCMCIA Mode JTAG Control Block TRST TMS/T3 TDI/T1 TDO/T2 RXCIN ANTSLT ANTSLT SAR6–0 ADIN2–1 ADREF RXDATA SDCLK SDDATA SDSEL3–1 TXCMD TXCMD TXMOD TXDATA TXDATA RXPE TXPE HFPE HFCLK LFPE LFCLK FDET LNK ACT RXC Transceiver Attachment Interface MAC Control Unit (80188 core) Bus Interface Unit (PCMCIA) MOE MW[...]
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Seite 4
4 Am79C930 PRELIMINARY BLOCK DI A GRAM Bus Interface Unit A14–0 or LA23–17, SA16–0 D7–0 CLKIN Slave Control PCMCI A and IS A Memory and I/O Address Bu f fer Data Bu f fer SIR0 System Interrupt Generator SIR1 ... SIR7 IS A Memory Base IS A I/O Base MD[7:0] MA[16:0] 80188 Interrupt Generator IREQ PCMCI A Config Registers ALE CA16 Latch Bus Mu[...]
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Seite 5
Am79C930 5 PRELIMINARY BLOCK DI A GRAM T ransceiver Atta c hment Interface Unit C R C MA[4:0] MD[7:0] CLKIN Slave Control Memory Interface Bus I/O and DMA TIR0 Interrupt Generator TCR31 TX FIFO 8 Bytes TXD RESET TCR.. . TIR... TIR31 TCR0 IRQ DRQ[1:0] RX FIFO 15 Bytes P->S S->P C R C RXD SFD Detect FDET ÷40 ÷5 ÷10 ÷20 M U X TXC DPLL M U X [...]
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Seite 6
AMD P R E L I M I N A R Y 6 Am79C930 TABLE OF CONTENTS DISTINCTIVE CHARACTERISTICS 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . GENERAL DESCRIPTION 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ORDER[...]
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Seite 7
P R E L I M I N A R Y AMD 7 Am79C930 Pin 3: USER4/LA17 34 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Pin 45: STSCHG/BALE 34 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Pin 90: USER0/RFRSH 34 . . . . . . [...]
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Seite 8
AMD P R E L I M I N A R Y 8 Am79C930 Bus Interface Unit Interaction 47 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transceiver Attachment Interface Unit 47 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . TX FIFO 48 . . . . . . . . . . . . . . . . . .[...]
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Seite 9
P R E L I M I N A R Y AMD 9 Am79C930 LED Support 73 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . RESET Methods 73 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . RESET Pin 73 . [...]
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Seite 10
AMD P R E L I M I N A R Y 10 Am79C930 TIR10: TX FIFO Data Register 95 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . TIR11: Transmit Sequence Control 95 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . TIR12: Byte Count Register LSB 96 [...]
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Seite 11
P R E L I M I N A R Y AMD 11 Am79C930 TCR24: RSSI Sample Start 117 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . TCR25: RSSI Configuration 118 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . TCR26: Reserved 119 . . . . . . .[...]
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Seite 12
AMD P R E L I M I N A R Y 12 Am79C930 TIMING WAVEFORMS 148 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PCMCIA Bus Interface Waveforms 148 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ISA Bus Interface Wavefo[...]
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Seite 13
Am79C930 13 PRELIMINARY PCMCIA CONNECTION DI A GRAM Notes: Pin 1 is marked f or orientation. NC = No Connection 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 56 57 58 59 60 61 62 98 99 100 101 102 103 104 54 55 53 108 107 106 105 31 4 5 6 7 8 9 10 1 1 1 2 3 28 29 30 12 13 14 15 16 17 18 19 [...]
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Seite 14
1 4 Am79C930 PRELIMINARY PCMCIA PIN SUMMA R Y Listed b y Pin Number Pin No. Pin Name Pin No. Pin Name Pin No. Pin Name Pin No. Pin Name 1 USER2 37 MA10 73 D7 109 SAR1 2 USER3 38 MOE 74 D6 110 SAR2 3 USER4 39 SCE 75 D5 111 SAR3 4 VDDM 40 FCE 76 VSSP 112 SAR4 5 XCE 41 D2 77 D4 113 SAR5 6 MA11 42 D1 78 D3 114 SAR6 7 VSSM 43 D0 79 PCMCIA 115 TXC 8 MA9 [...]
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Seite 15
Am79C930 15 PRELIMINARY PCMCIA PIN LIST Listed b y Pin Name Pin Name Pin No. Pin Name Pin No. Pin Name Pin No. Pin Name Pin No. A0 46 HFPE 120 OE 70 TXMOD 131 A1 47 INP ACK 50 PCMCIA 79 TXPE 129 A10 71 IORD 67 PMX1 83 USER0 90 A11 69 IO WR 66 PMX2 82 USER1 91 A12 56 IREQ 61 PWR D WN 133 USER2 1 A13 64 LFCLK 117 REG 48 USER3 2 A14 63 LFPE 118 RESET [...]
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Seite 16
1 6 Am79C930 PRELIMINARY PCMCIA PIN FUNCTION SUMMA R Y PCMCIA Pin Summary No . of Pins Pin Name Pin Function Pin Style 15 A14–A0 PCMCIA address b us lines I 8 D7–D0 PCMCIA data b us lines TS2 1 RESET PCMCIA b us RESET line I 1 CE1 Card Ena b le 1—used to ena b le the D7–0 pins f or PCMCIA Read an d W r ite accesses I 1 OE Output Ena b le—[...]
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Seite 17
Am79C930 1 7 PRELIMINARY PCMCIA PIN FUNCTION SUMMA R Y (continued) PCMCIA Pin Summary (conti n ued) No . of Pins Pin Name Pin Function Pin Style 1 TDO T est Data Out—this is the data output signal f or IEEE 1149.1 testing TS1 1 TMS T est Mode Select—this is the test mode select f or IEEE 1149.1 testing I 1 TRST T est Reset—this is the reset s[...]
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Seite 18
1 8 Am79C930 PRELIMINARY PCMCIA PIN FUNCTION SUMMA R Y (continued) PCMCIA Pin Summary (conti n ued) Output Drive r T ypes Inpu t T ypes No . of Pins Pin Name Pin Function Pin Style 2 ADIN1–2 Comparator—A/D comparator inputs TS1 12 V CC P o wer I 13 GND Ground I 7 USER0–USER6 User-defina b le I/O pins with direct accessibility and control thr[...]
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Seite 19
Am79C930 1 9 PRELIMINARY ISA PLUG AND PL A Y BLOCK DI A GRAM JTAG Control Block TRST TMS/T3 TDI/T1 TDO/T2 RXCIN ANTSLT ANTSLT SAR6–0 ADIN2–1 ADREF RXDATA SDCLK SDDATA SDSEL3–1 TXCMD TXCMD TXMOD TXDATA TXDATA RXPE TXPE HFPE HFCLK LFPE LFCLK FDET LNK ACT RXC IEEE 802.11 Network Interface Unit IEEE 802.11 MAC Control Unit (80188 core) Bus Interf[...]
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Seite 20
20 Am79C930 PRELIMINARY ISA PLUG AND PL A Y CONNECTION DI A GRAM Notes: Pin 1 is marked f or orientation. NC = No Connection 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 56 57 58 59 60 61 62 98 99 100 101 102 103 104 54 55 53 132 131 130 129 128 127 126 125 124 123 122 144 143 142 141 140 [...]
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Seite 21
Am79C930 21 PRELIMINARY ISA PLUG AND PL A Y PIN LIST Listed b y Pin Number Pin No. Pin Name Pin No. Pin Name Pin No. Pin Name Pin No. Pin Name 1 LA19 37 MA10 73 SD7 109 SAR1 2 SA16 38 MOE 74 SD6 110 SAR2 3 LA17 39 SCE 75 SD5 111 SAR3 4 VDDM 40 FCE 76 VSSP 112 SAR4 5 XCE 41 SD2 77 SD4 113 SAR5 6 MA11 42 SD1 78 SD3 114 SAR6 7 VSSM 43 SD0 79 PCMCIA 11[...]
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Seite 22
22 Am79C930 PRELIMINARY ISA PLUG AND PL A Y PIN LIST Listed b y Pin Name Pin Name Pin No. Pin Name Pin No. Pin Name Pin No. Pin Name Pin No. A CT 98 MA11 6 SA1 47 SDSEL2 105 ADIN1 134 MA12 15 SA10 71 SDSEL3 103 ADIN2 135 MA13 10 SA11 69 TCK 84 ADREF 137 MA14 12 SA12 56 TDI 88 AEN 48 MA15 14 SA12 56 TDO 85 ANTS L T 132 MA16 13 SA13 64 TEST 81 A VDD [...]
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Seite 23
Am79C930 23 PRELIMINARY ISA PLUG AND PL A Y PIN SUMMA R Y No . of Pins Pin Name Pin Function Pin Style 7 LA23–LA17 ISA upper address b us lines I 17 SA16–SA0 ISA l o wer address b us lines I 8 SD7–SD0 ISA data b us lines TS2 1 RESET RESET input I 1 MEMR Memo r y Read—used to ena b le the output d r i v ers of the Am79C930 d e vice f or ISA [...]
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Seite 24
24 Am79C930 PRELIMINARY ISA PLUG AND PL A Y PIN SUMMA R Y (continued) Output Drive r T ypes Inpu t T ypes No . of Pins Pin Name Pin Function Pin Style 1 TXC T ransmit Clo c k—m a y be configured either as input or output TS1 1 LFPE L o w F requency P o wer Ena b le—used to p o wer up the l o w-frequency section of the t r anscei v er PTS1 1 LF[...]
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Seite 25
P R E L I M I N A R Y AMD 25 Am79C930 PIN DESCRIPTIONS Pins with Internal Pull Up or Pull Down Devices Several pins of the Am79C930 device include internal pull up or pull down devices. With the exception of the RESET pin, these pins are fully programmable as inputs or outputs when the PCMCIA mode has been selected. A subset of these pins is progra[...]
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Seite 26
AMD P R E L I M I N A R Y 26 Am79C930 The functionality of the following pins is determined, at least in part, by the connection of the PCMCIA pin: PCMCIA Mode ISA Plug and Play Mode Pin Name Pin Name USER6 USER6/IRQ5 USER5 USER5/IRQ4 USER4 LA17 USER3 SA16 USER2 LA19 USER1 USER1/IRQ12 USER0 RFRSH A[14:0] SA[14:0] LLOCKE SA15 D[7:0] SD[7:0] CE1 LA18[...]
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Seite 27
P R E L I M I N A R Y AMD 27 Am79C930 Function Mode REG CE1 IORD IOWR A0 OE WE D7–0 Standby mode X H X X X X X High-Z Common Memory Read Even Byte H L H H L L H Even Byte Common Memory Read Odd Byte H L H H H L H Odd Byte Common Memory Write Even Byte H L H H L H L Even Byte Common Memory Write Odd Byte H L H H H H L Odd Byte Attribute Memory Rea[...]
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Seite 28
AMD P R E L I M I N A R Y 28 Am79C930 IOR I/O Read Input The IOR signal is made active by the ISA host in order to read data from the Am79C930 device’s I/O space. IOW I/O Write Input The IOW signal is made active by the ISA host in order to write data to the Am79C930 device’s I/O space. MEMR Memory Read Input The MEMR signal is made active by t[...]
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Seite 29
P R E L I M I N A R Y AMD 29 Am79C930 Clock Pins CLKIN System Clock Input CLKIN is the clock input for the Am79C930 device’s logic functions. CLKIN is used to drive the CLKIN input of the embedded 80188 core. The BIU section uses the CLKOUT signal from the 80188 embedded core as a reference. The register interface portions of the TAI use the CLKI[...]
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Seite 30
AMD P R E L I M I N A R Y 30 Am79C930 is deasserted when the RESET pin is issued or the CRC reset bit is set to 1 (SIR0); when the TXS bit is set to 1 (TIR8) or the RXS bit is set to 1 (TIR16); when TXRES bit set to 1 (TIR8), or the RXRES bit is set to 1 (TIR16), or the SRES bit is set to 1 (TIR0). HFCLK High Frequency Clock Output HFCLK provides a[...]
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Seite 31
P R E L I M I N A R Y AMD 31 Am79C930 TXMOD Transmit Modulation Enable Output TXMOD is an active low output that is used to enable the transmit modulation function of the attached trans- ceiver. This pin is directly controlled by the transmit state machine in the TAI and the TXMOD bit of TIR11. The timing of the TXMOD signal is programmable from a [...]
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Seite 32
AMD P R E L I M I N A R Y 32 Am79C930 IEEE 1149.1 Test Access Port Pins TCK Test Clock Input TCK is the clock input for the boundary scan test mode operation. TCK frequency may be as high as 10 MHz. TCK does not have an internal pull-up resistor and must be connected to a valid TTL or CMOS level at all times. TCK must not be left unconnected. TDI T[...]
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Seite 33
P R E L I M I N A R Y AMD 33 Am79C930 VDDT, VDDU1, VDDU2, VDDP, Acceptable VCC VDDM AVDD, VDD5 Combination 5 V All at 5 V Both at 5 V Yes 3 V All at 5 V Both at 5 V Yes 3 V Any Combination Both at 5 V Yes of 3 V and 5 V 3 V All at 3 V Both at 5 V Yes 5 V All at 3 V Both at 5 V No 5 V Any Combination Both at 5 V No of 3 V and 5 V 5 V All at 5 V Any [...]
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Seite 34
AMD P R E L I M I N A R Y 34 Am79C930 for an output function. This means that there are con- figurations for which a read of the pin data register bit will not reflect what has most recently been written to the pin data register bit ( i.e., if a pin is configured as an output with its data source as some internal circuit, then the user may write th[...]
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Seite 35
P R E L I M I N A R Y AMD 35 Am79C930 Note that a read of the USERDT[0] bit (TIR29[0]) will al- ways give the current USER0/RFRSH pin value, regard- less of pin configuration setting. Pin 91: USER1/IRQ12/EXTCTS/EXINT188 The USER1/IRQ12 pin may be configured for input operation, output operation, or ISA IRQ12 operation ac- cording to the following t[...]
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Seite 36
AMD P R E L I M I N A R Y 36 Am79C930 Pin 94: RXC/IRQ10/EXTA2DST The RXC/IRQ10 pin may be configured for input opera- tion, output operation, ISA IRQ10 operation, and as an output providing the RX clock information (whether de- rived from the RXDATA stream through Am79C930 device DPLL operation or simply rerouted from the RXCIN input) according to [...]
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Seite 37
P R E L I M I N A R Y AMD 37 Am79C930 ENXCHBSY bit of TCR28 and the CHBSYU bit of TIR5 and operates independently of the bits in the table below. In addition to the functionality listed above, the USER5/IRQ4/EXTCHBSY pin may be used as the source for CCA information, instead of relying on the in- ternal CCA logic of the Am79C930 device. When using [...]
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Seite 38
AMD P R E L I M I N A R Y 38 Am79C930 Pin 101: SDCLK The SDCLK pin may be configured for input or output operation. The output drive may be programmed for reg- ister-driven or auto-pulse generation. The auto-pulse may be programmed for either active low or active high operation. SDCLK pin configuration is accomplished ac- cording to the following t[...]
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Seite 39
P R E L I M I N A R Y AMD 39 Am79C930 Pin 115: TXC The TXC pin may be configured for input or output op- eration according to the table below: TXC input configuration is the reset default configura- tion. This configuration allows an external transceiver to control the clock that serves as the reference for the transmit data. While in this configur[...]
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Seite 40
AMD P R E L I M I N A R Y 40 Am79C930 Pin 126: TXCMD The TXCMD pin may be configured to drive a trans- ceiver control reference signal, using one of two timing sources plus input from the TXCMD bit of TIR11 (TIR11[0]), according to the following table: RCEN TXCMD Pin TXCMD Pin TIR11[3] Direction Value 0 O O_TX 1O TIR11 [ 0 ] & T1 Transmit state[...]
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Seite 41
P R E L I M I N A R Y AMD 41 Am79C930 some functionality is only available in PCMCIA mode. Pin functionality is programmed according to the follow- ing table: Note that a read of the ANTSLTD bit (TCR7[1]) will al- ways give the current ANTSLT /LA23 pin value without inversion, regardless of pin configuration setting. ANTSLT / ANTSLT / PCMCIA ANTSEN[...]
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Seite 42
AMD P R E L I M I N A R Y 42 Am79C930 LLOCKE/ LLOCKE/ PCMCIA LLOCKEN SA15 Pin SA15 Pin Pin Value TCR14[6] Direction Value 0 X I NA (SA15 input function) 10 I N A 1 1 O TIR11[4] FUNCTIONAL DESCRIPTION Basic Functions System Bus Interface Function The Am79C930 device is designed with a choice of two system bus interfaces. The system designer may choo[...]
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Seite 43
P R E L I M I N A R Y AMD 43 Am79C930 PCMCIA Interface — The Am79C930 device fully sup- ports the PCMCIA standard, revision 2.1. The PCMCIA interface on the Am79C930 device sup- ports both memory and I/O cycles. The data bus is 8 bits in width. The address bus is 15 bits in width. Memory ac- cesses are enabled by default at power up. I/O ac- cess[...]
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Seite 44
AMD P R E L I M I N A R Y 44 Am79C930 ISA (IEEE P996) Plug and Play Interface — The Am79C930 device fully supports the ISA Plug and Play specification, revision 1.0a. The ISA Plug and Play interface on the Am79C930 de- vice supports both memory and I/O cycles. The data bus is 8 bits in width. The total system space required by the Am79C930 device[...]
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Seite 45
P R E L I M I N A R Y AMD 45 Am79C930 Memory Interface The memory interface is provided to support direct con- nection of both a non-volatile memory (typically Flash memory) and an SRAM and an additional peripheral de- vice. Separate chip enables for Flash, SRAM, and an extra peripheral device exist in the memory interface. The 32K range of address[...]
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Seite 46
AMD P R E L I M I N A R Y 46 Am79C930 the media is considered busy and the MAC should defer to the existing message. This function is implemented in hardware in the TAI Unit. Additionally, each station is required to implement a Net Allocation Vector (NAV) in order to determine when the medium is expected to be busy. The NAV is updated as Request-t[...]
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Seite 47
P R E L I M I N A R Y AMD 47 Am79C930 accesses to use the memory interface bus during the T1 and T2 cycles of the 80188 access. The Memory Ad- dress Bus is internally shared between the 80188 core and the BIU. This bus also attaches to the Transceiver Attachment Unit as an input only. Data values are delivered from the 80188 core to the SRAM throug[...]
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Seite 48
AMD P R E L I M I N A R Y 48 Am79C930 Transceiver Attachment Interface Unit The TAI Unit includes the following subfunctions: TAI register set TX FIFO TX data serialization TX CRC32 generation TX CRC8 generation TX status reporting RX preamble and Start of Frame detection RX data deserialization RX FIFO RX CRC32 checking RX CRC8 checking RX status [...]
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Seite 49
P R E L I M I N A R Y AMD 49 Am79C930 T1 TXD A T A T2 T3 2 X TSCLK TGAP2 X TBCLK + 2 X TSCLK TGAP1 X TBCLK + 2 X TSCLK 1st Data Bit Last Data Bit 2 X TSCLK TXS 4 X TSCLK TSCLK = TCLKIN when CLKGT20 = 0 TBCLK = TSCLK X 20 TGAP3 X TBCLK + 2 X TSCLK O_TX TXP_ON 3 X TSCLK HDB X TBCLK TX default bit DRB X TBCLK TGAP4 X TBCLK + 2 X TSCLK TX defaul[...]
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Seite 50
AMD P R E L I M I N A R Y 50 Am79C930 Transceiver-Based TX Power Ramp Control — The CTS signal may be used to synchronize operations be- tween the Am79C930 device and transceivers that wish to perform their own transmit timing sequence. When the CTS signal is enabled by setting the CTSEN bit of TCR7 to a 1, then the CTS input acts as a gating sig[...]
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Seite 51
P R E L I M I N A R Y AMD 51 Am79C930 values were found to be correct. These register values can be used to determine the end of a received frame. When good CRC values are found, these may be sig- naled to the 80188 core through interrupt bits in TIR5. The CRC32 polynomial is X32+X26+X23+X22+X16 +X12+X11+X10+X8+X7+X5+X4+X2+X+1; the initial conditio[...]
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Seite 52
AMD P R E L I M I N A R Y 52 Am79C930 register of TCR4. ADIN2 becomes active after ADIN1 by the amount of delay specified in the RSSI Sample Start time of TCR24. ADIN2 remains active for the time pro- grammed in the A2DT register (TCR25). The converter output should be connected to the SAR pins, which act as inputs in this mode. External D/A mode a[...]
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Seite 53
P R E L I M I N A R Y AMD 53 Am79C930 resolution is equal to twice the CLKIN period when the CLKGT20 bit of MIR9 is set to 1. (For a 1 MB data rate with CLKIN = 20 MHz and CLKGT20 = 0, resolution is 50 ns.) After each pair of rising edges is detected, the value of the rising edge separation counter is compared against the Baud Detect upper limit re[...]
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Seite 54
AMD P R E L I M I N A R Y 54 Am79C930 CCA Result UBDCS URSSI Baud Detect Carrier RSSI >= RSSI (CHBSY Bit TCR28:1 TCR28:0 Sense Decision Lower Limit of TIR26) 0 0 don’t care don’t care CHBSY = TRUE 0 1 don’t care yes CHBSY = TRUE 0 1 don’t care no CHBSY = FALSE 1 0 TRUE don’t care CHBSY = TRUE 1 0 FALSE don’t care CHBSY = FALSE 1 1 TR[...]
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Seite 55
P R E L I M I N A R Y AMD 55 Am79C930 Diversity decision logic for determining if a satisfactory antenna has been found. These inputs to the Stop Di- versity decision logic are enabled by specific bits of TCR28. The UBDSD bit of TCR28 is used to select/ deselect the Baud Determination of Stop Diversity for use in Stop Diversity decisions and the UR[...]
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Seite 56
AMD P R E L I M I N A R Y 56 Am79C930 The following is a brief summary of the IEEE 1149.1 compatible test functions implemented in the Am79C930 device: Boundary Scan Circuit The boundary scan test circuit uses five pins: TRST, TCK, TMS, TDI, and TDO. These five pins are collec- tively labeled the TAP. The boundary scan test circuit in- cludes a fin[...]
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Seite 57
P R E L I M I N A R Y AMD 57 Am79C930 mode, the host requests a power down by writing to the Power Down bit (bit 2) of the PCMCIA Card Configura- tion and Status Register. In the ISA Plug and Play mode, the host requests a power down by writing to the ISA Power Down bit, bit 7 of SIR3. In either case, the power down request will generate an interru[...]
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Seite 58
AMD P R E L I M I N A R Y 58 Am79C930 Writing a 1 to the Power Down bit of the ISA Power Down bit of SIR3 will cause a request for a power down to be generated to the 80188 core via an interrupt bit in MIR0. The decision to power down will be made by the 80188 controller, and the actual power down command will be executed by the 80188 controller by[...]
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Seite 59
P R E L I M I N A R Y AMD 59 Am79C930 Am79C930 Device PCMCIA Mode Resource Requirements Common Common Attribute Attribute Memory Range Memory Size I/O Range I/O Size Memory Range Memory Size 0000h – 7FFFh 32 Kbytes 0000h – 0027h 40 0000h – 0803h 2 K+4 bytes OR OR OR 0 bytes 0000h – 000Fh 16 bytes The I/O range is adjusted through bit 2 (EIO[...]
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Seite 60
AMD P R E L I M I N A R Y 60 Am79C930 Some of the Am79C930 device’s PCMCIA Common Memory locations have predefined uses and, therefore, are not freely available to the device driver. The following table indicates restricted space within PCMCIA Common Memory map of the Am79C930 device: Am79C930 Device PCMCIA Mode Common Memory Restricted Space PCM[...]
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Seite 61
P R E L I M I N A R Y AMD 61 Am79C930 The SRAM is intended to serve as a shared memory re- source between the driver operating through the system interface and the 80188 core operating through the Am79C930 memory interface bus. Even though SRAM memory locations 0 0400h through 0 043Fh are acces- sible from the system interface, these locations cann[...]
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AMD P R E L I M I N A R Y 62 Am79C930 Am79C930 Device PCMCIA Mode Attribute Memory Restricted Space PCMCIA Address in Attribute Memory SIR1[5:3] Size of Restricted Space Physical Memory and Description of Reserved Use 7FE0h – 7FFFh 111 32 bytes of Attribute Flash Memory 1 FFF0h – 1 FFFFh memory, 16 bytes of actual These 16 bytes of Flash memory[...]
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Seite 63
P R E L I M I N A R Y AMD 63 Am79C930 The following table indicates the mapping of all I/O re- sources that are accessible through the Am79C930 PCMCIA system interface. Note that some resources are physically located within the BIU, while others are lo- cated in the TAI and still others exist as external Flash and SRAM: Am79C930 Device PCMCIA Mode [...]
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AMD P R E L I M I N A R Y 64 Am79C930 Am79C930 Device ISA Plug And Play Mode Memory And I/O Resource Requirements Memory Range Memory Size I/O Range I/O Size MBA*+0000h – 32 Kbytes IOBA**+0000h – IOBA**+000Fh 16 bytes MBA*+7FFFh OR and I/O 0279h and I/O 0A79h 0 bytes and I/O 0203h – I/O 03FFh (one byte only) *MBA = ISA Plug and Play Memory Ba[...]
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Seite 65
P R E L I M I N A R Y AMD 65 Am79C930 address needs to be aligned to a 32K boundary in mem- ory space. This alignment requirement should be in- cluded in the Resource Data that is programmed into the Flash device and read by the Plug and Play configura- tion utility. These conditions must be satisfied, since the Am79C930 device’s Bus Interface Un[...]
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Seite 66
AMD P R E L I M I N A R Y 66 Am79C930 The SRAM is intended to serve as a shared memory re- source between the driver operating through the system interface and the 80188 core operating through the Am79C930 memory interface bus. Even though SRAM memory locations 0 0400h through 0 043Fh are acces- sible from the system interface, these locations cann[...]
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Seite 67
P R E L I M I N A R Y AMD 67 Am79C930 Am79C930 Device ISA Plug And Play Mode I/O MAP Physical ISA SIR1 Resource Location of Resource Name Mnemonic I/O address Bits [2:0] Size Resource SIR0: General SIR0: GCR IOBA*+0000h XXX** 1 byte BIU Configuration Register SIR1: Bank Switching SIR1: BSS IOBA+0001h XXX 1 byte BIU Select Register SIR2: Local Memor[...]
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AMD P R E L I M I N A R Y 68 Am79C930 ISA Plug and Play Register Set — The Am79C930 de- vice fully supports the ISA Plug and Play specification, revision 1.0a. The Am79C930 device supports the Plug and Play Auto-configuration scheme. The Plug and Play ADDRESS Auto-configuration Port, WRITE_DATA Auto-configuration Port, and READ_DATA Auto-con- fig[...]
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Seite 69
P R E L I M I N A R Y AMD 69 Am79C930 Am79C930 Device ISA Plug And Play Mode Plug And Play Register Set ISA Plug and Play Plug and Play Port Register Name ADDRESS Physical Location Set READ_DATA port 00h BIU Serial Isolation 01h BIU Configuration Control 02h BIU Wake [CSN] 03h BIU Resource Data 04h Flash Memory 1 FC00h–1 FFF0h Total of 1K–16 by[...]
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AMD P R E L I M I N A R Y 70 Am79C930 The Am79C930 device maps the Resource Data regis- ter accesses into 1K–16 of the upper 1 Kbytes of the Flash memory space so that Resource Data may be read from the Flash memory. Byte 0 of the Am79C930 device’s Resource Data is mapped to location 1 FC00h of the Flash memory. A maximum of 1K–16 bytes of Re[...]
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Seite 71
P R E L I M I N A R Y AMD 71 Am79C930 80188 Core Memory Map Using Scheme “A”, LMCS=1FF8h, UMCS=E038h, MIR0[6]=0 Active 80188 Address Active 80188 Am79C930 Size of in Memory Chip Select Chip Select Space Physical Location of Memory 0 0000h–0 03FFh LCS SCE 1 Kbytes SRAM Memory 0 0000h–0 03FFh 0 0400h–0 041Fh LCS none 32 bytes TIR 0–31 0 0[...]
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Seite 72
AMD P R E L I M I N A R Y 72 Am79C930 MAC (80188 core) Memory Resources Restrictions — Some of the Am79C930 device 80188 core’s memory locations have predefined uses and, therefore, are not freely available to the firmware. The following table indicates restricted space within the 80188 core memory map of the Am79C930 device: Restricted Space I[...]
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Seite 73
P R E L I M I N A R Y AMD 73 Am79C930 to TIR10. It is also possible to use 80188 MOV instruc- tions to unload RX data from the RX FIFO. The RX FIFO may be unloaded by reading from TIR18. DMA Channel Allocation In The 80188 Core 80188 DMA Channel DMA Request Source DRQ0 TAI RX FIFO NOT EMPTY DRQ1 TAI TX FIFO NOT FULL Loopback Operation The Am79C930 [...]
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AMD P R E L I M I N A R Y 74 Am79C930 The sleep state machine is returned to its idle state (i.e., awake). The memory bus arbitration state machine is re- turned to its idle state. The following registers and state machines which are UNAFFECTED by assertion of the SWRESET bit of SIR0[7]: SIR0[7] and all of SIR2[7:0] and SIR3[6:0] are unaf- fected b[...]
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Seite 75
P R E L I M I N A R Y AMD 75 Am79C930 The sleep state machine is returned to its idle state (i.e., awake). The following registers and state machines are UNAFFECTED by assertion of the PCMCIA COR SRESET bit of COR[7]: All TIR registers are unaffected by COR SRESET. All TCR registers are unaffected by COR SRESET. All TAI state machines are unaffecte[...]
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Seite 76
AMD P R E L I M I N A R Y 76 Am79C930 The MIR space contains 16 registers which are used by the firmware to control allow communication between the firmware (MAC layer) and the device driver. This register set also contains the power down registers. These registers are only accessible through the 80188 core; they are inaccessible from the system in[...]
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Seite 77
P R E L I M I N A R Y AMD 77 Am79C930 SIR0: General Configuration Register (GCR) This register is used to control general functions related to the Am79C930, particularly interrupts to and from the 80188 core and power down functions. Bit Name Reset Value Description 7 SWRESET 0 Software Reset. When SWRESET is set to a 1, the BIU will be RESET, with[...]
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AMD P R E L I M I N A R Y 78 Am79C930 2 INT2EC 0 Interrupt to Embedded Controller. When INT2EC is set to a 1, an interrupt is sent to the 80188 core. INT2EC will stay set at 1 until the 80188 core clears this bit by writing a 1 to bit 3 of the MIR0 register. Writing a 0 to INT2EC will have no effect on the value of INT2EC. 1 ENECINT 0 Enable Embedd[...]
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Seite 79
P R E L I M I N A R Y AMD 79 Am79C930 SIR2: Local Memory Address Register [7:0] (LMA) This register is the beginning address on the local bus for system interface I/O transfers that are made to the I/O Data Port. This register automatically increments by “1” following each read or write operation of any section of the I/O Data Port. (MA[16:15] [...]
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AMD P R E L I M I N A R Y 80 Am79C930 SIR5: I/O Data Port B (IODPB) This register is a system interface I/O address alias of I/O Data Port A. Bit Name Reset Value Description 7:0 IODPB[7:0] – Aliased to I/O Data Port A. SIR6: I/O Data Port C (IODPC) This register is a system interface I/O address alias of I/O Data Port A. Bit Name Reset Value Des[...]
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Seite 81
P R E L I M I N A R Y AMD 81 Am79C930 4 PDC 0 Power Down Command. When PDC is set to 1, the power down cy- cle of the BIU power down state machine will begin. PDC will auto- matically clear itself after completion of the power down operation. 3 SYSINT 0 System Interrupt. SYSINT Indicates a 1 after the system issues an interrupt command to the 80188[...]
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AMD P R E L I M I N A R Y 82 Am79C930 MIR3: Power Down Length Count [15:8] (PDLC) This register is used to determine the length of power down cycles. Before execution of the power down se- quence, the 80188 core must load the PDLC counter. Upon execution of the power down sequence, the PDLC value will be counted down to zero and the power down cycl[...]
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P R E L I M I N A R Y AMD 83 Am79C930 MIR8: Flash Wait States This register gives the Flash Wait states. Bit Name Reset Value Description 7:4 Reserved – Reserved. Must be written as a 0. Reads of this bit produce undefined data. 3 HOSTALLOW 1 When this bit equals 1, then the host can access memory; if 0, then the host access is blocked completely[...]
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AMD P R E L I M I N A R Y 84 Am79C930 6 Reserved – Reserved. Must be written as a 0. Reads of this bit produce undefined data. 5:4 SRAMWAIT[1:0] 11b These bits must be set equal to or greater than the number of wait states that are generated internally in the 80188 core as defined by the programming of the R1 and R0 bits of the 80188 LMCS registe[...]
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Seite 85
P R E L I M I N A R Y AMD 85 Am79C930 PCMCIA CCSR is RESET to a 0. If the STSCHGFN bit of TCR15 has been set to a 0, then the value that is written to this bit will be inverted and driven to the STSTCHG pin of the Am79C930 device. The value that is read from this bit always represents the inverse of the current value of the STSTCHG pin of the Am79C[...]
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Seite 86
AMD P R E L I M I N A R Y 86 Am79C930 Transceiver Attachment Interface Registers (TIR Space) The Transceiver Attachment Interface (TAI) Unit con- tains a total of 64 registers. Thirty-two of the registers are directly accessible from the 80188 embedded core and from the system interface through the BIU. The other 32 registers are indirectly accesse[...]
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Seite 87
P R E L I M I N A R Y AMD 87 Am79C930 TIR mapping with SIR1 bit 2 (EIOW) set to “0” = normal TIR window mode. Note that EIOW = 0 is the only setting of EIOW that is allowed while operating in ISA PnP mode. TIR uses eight I/O addresses: TIR SIR1[1:0] ISA Plug 80188 Core Register (TAI Bank PCMCIA and Play Address in Number TIR Register Name Selec[...]
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AMD P R E L I M I N A R Y 88 Am79C930 TIR mapping with SIR1 bit 2 (EIOW) set to “1” = Ex- panded TIR window mode. Note that the setting EIOW = 1 is only allowed while operating in PCMCIA mode. TIR uses 32 I/O addresses: TIR SIR1[1:0] 80188 Core Register (TAI Bank PCMCIA Address in Number TIR Register Name Select) I/O Address Memory 0 Network Co[...]
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Seite 89
P R E L I M I N A R Y AMD 89 Am79C930 TIR0: Network Control General control for the transceiver device attached to the transceiver interface pins. Bit Name Reset Value Description 7 LNK pin Link LED. The inverse of the LNK bit value is driven onto the LNK pin when the LNK pin has been enabled for output. The value read from LNK will always represen[...]
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AMD P R E L I M I N A R Y 90 Am79C930 1 RXDRQ 0 Receive FIFO DMA Request. This bit represents the current value of the RXDRQ signal to the DRQ0 input of the 80188 embedded core. 0 TXDRQ 1 Transmit FIFO DMA Request. This bit represents the current value of the TXDRQ signal to the DRQ1 input of the 80188 embedded core. TIR2: Serial Device TAI Serial [...]
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Seite 91
P R E L I M I N A R Y AMD 91 Am79C930 The value read from SDD will always represent the current value of the SDDATA pin. The complete control of the function of the SDDATA pin is described in the Multi-Function Pin section. When the fast serial port (TIR3) is used, then the value written to SDD will be exclusive OR’d (XOR) with the data from the [...]
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Seite 92
AMD P R E L I M I N A R Y 92 Am79C930 5 MOREINT 1 MORE Interrupts. MOREINT will become set whenever there are interrupt bits set in Interrupt Register 3 (TCR11). Note that MOREINT bit does not reflect the state of interrupt status bits from Interrupt Register 2 (TIR5). There is an unmask bit for MOREINT, and there are also individual unmask bits fo[...]
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Seite 93
P R E L I M I N A R Y AMD 93 Am79C930 (Generated from the internal signal stop_d, which indicates that an- tenna diversity operation has selected an antenna.) Assertion of ALOKI indicates the cessation of antenna diversity activity so that the incoming network signal can be tracked and decoded by the DPLL. ALOKI will be set to a 1 by the Am79C930 d[...]
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Seite 94
AMD P R E L I M I N A R Y 94 Am79C930 TIR8: Transmit Control This register is the Transmitter Control register. Bit Name Reset Value Description 7 TXRES 0 Transmit Reset. When this bit is set to 1, the internal Transmit Re- set signal is asserted. When this bit is set to 0, the internal Transmit Reset signal is deasserted. The transmit FIFO is NOT [...]
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Seite 95
P R E L I M I N A R Y AMD 95 Am79C930 TIR9: Transmit Status Transmit Status register. Indicates the current status of the Transmit portion of the TAI. Writes to these bits have no effect. Bit Name Reset Value Description 7 TXCRC 0 Transmit CRC. TXCRC becomes set when the CRC is being ap- pended to the end of the transmit frame. TXCRC is reset when [...]
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Seite 96
AMD P R E L I M I N A R Y 96 Am79C930 TIR11: Transmit Sequence Control This register is the Transmit Sequence Control. The bits in this register determine the function of the transmit sequence signals. Bit Name Reset Value Description 7 RXCD pin RXC/IRQ10 pin Data. The value that is written to this bit will be driven out to the RXC pin when the RXC[...]
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Seite 97
P R E L I M I N A R Y AMD 97 Am79C930 TIR12: Byte Count Register LSB This register is the Byte count register LSB. This register contains the lower 8 bits of the 12-bit byte count for receive and transmit messages. This is a working register; access by software is not needed for normal operation. Bit Name Reset Value Description 7:0 BC[7:0] 00h Byt[...]
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Seite 98
AMD P R E L I M I N A R Y 98 Am79C930 TIR15: Byte Count Limit MSB This register is the Byte Count Limit MSB register. Bit Name Reset Value Description 7–4 Reserved – Reserved. Must be written as a 0. Reads of this bit produce undefined data. 3–0 BCLT[11:8] 0h Byte Count Limit. Upper 4 bits of byte count limit for both transmit and receive ope[...]
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Seite 99
P R E L I M I N A R Y AMD 99 Am79C930 5 RXFOR 0 Receive FIFO Overrun. This bit is set whenever the RX FIFO expe- riences an overrun. This bit is cleared by resetting the RX FIFO. 4–1 RXFC[3:0] 0 Receive FIFO Count. These bits indicate the current count of the number of bytes contained in the RX FIFO. The RX FIFO holds 15 bytes. An RXFC value of ?[...]
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Seite 100
AMD P R E L I M I N A R Y 100 Am79C930 TIR21: CRC32 Correct Byte Count MSB This register is the CRC32 Correct Byte Count MSB register. Bit Name Reset Value Description 7–4 Reserved – Reserved. Must be written as a 0. Reads of this bit produce undefined data. 3–0 C32C[11:8] – CRC32 Correct Count. The value in this register indicates the uppe[...]
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Seite 101
P R E L I M I N A R Y AMD 101 Am79C930 TIR24: TCR Index Register This register is the TCR Index register. This register is used as an address into indirect TAI register space. The value in the TCR Index Register is used as an address that points at one of 64 registers that are accessed through the TCR Data Port. Bit Name Reset Value Description 7:6[...]
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Seite 102
AMD P R E L I M I N A R Y 102 Am79C930 2 ADDA 0 A/D D/A mode. ADDA is used with ENEXT (TCR25[6]), ENSAR (TCR25[5]), and UXA2DST (TCR25[7]) to determine the mode of operation of the A/D portion of the Am79C930 device according to the following table: ADDA ENEXT ENSAR UXA2DST A/D TIR26[2] TCR25[6] TCR25[5] TCR25[7] mode 0 0 0 0 internal_A 0 0 0 1 res[...]
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Seite 103
P R E L I M I N A R Y AMD 103 Am79C930 TIR28: RSSI Lower Limit This register is the RSSI Lower Limit register. The value in this register is compared against converted RSSI in- put values. When the converted RSSI value is equal to or exceeds the value in this register, then an indication will be sent to the clear channel assessment logic. Bit Name [...]
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Seite 104
AMD P R E L I M I N A R Y 104 Am79C930 TIR31: TEST The TAI TEST register is a reserved location. Bit Name Reset Value Description 7 Reserved 0 These bit must be set to 0. Do not write to this register. 6–0 TC[6:0] 00h Test Command. The bits in this register are decoded to generate a test mode for the TAI. TAI Configuration Register Space (TCR) Th[...]
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Seite 105
P R E L I M I N A R Y AMD 105 Am79C930 Programmed SD[1:0] Start of Frame Detect Operation Register 00 Start of Frame Detect Off None 01 Search for 8 bit Start of Frame Delimiter TCR10 10 Search for 16 bit Start of Frame Delimiter TCR9, TCR10 11 Search for 24 bit Start of Frame Delimiter TCR8, TCR9 TCR10 TCR1: Transmit Configuration This register is[...]
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Seite 106
AMD P R E L I M I N A R Y 106 Am79C930 TCR2: Clock Recovery This register is the Clock Recovery Configuration register. Bit Name Reset Value Description CONFIGURATION REGISTER INDEX: 02h 7 WNS2 0 Bit Stuffing Start. When WNS2 is set to a 1, then the bit stuffing op- eration on RX and TX frames will begin after the PHY header field has passed. When [...]
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Seite 107
P R E L I M I N A R Y AMD 107 Am79C930 to delay the start of CRC8 and CRC32 and DC bias control calculation for both receive and transmit frames. The physical header field is assumed to begin after the Start of Frame Delimiter has been detected. TCR4: Antenna Diversity Timer This register is the Antenna Diversity Timer register used to control ante[...]
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Seite 108
AMD P R E L I M I N A R Y 108 Am79C930 TCR6: TX Ramp Down Timing This register is the TX Ramp Down Timing register. This register determines the ramp down timing of the TX enable signals. CONFIGURATION REGISTER INDEX: 06h Bit Name Reset Value Description 7:4 TGAP3[3:0] 0h Transmit Timing Gap 3. These bits are used to determine the gap between the d[...]
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Seite 109
P R E L I M I N A R Y AMD 109 Am79C930 In addition, the USER5/IRQ4 pin may be used to produce interrupts to the 80188 embedded controller. This capability is controlled by the ENXCHBSY bit of TCR28 and the CHBSYCU bit of TIR5 and operates independently of the bits mentioned above. The control of the function of the USER5/IRQ4 pin is described in th[...]
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Seite 110
AMD P R E L I M I N A R Y 110 Am79C930 has also been set to a 1 and the PCMCIA pin is set to 1. The value that is read from this bit represents the current value of the TXDATA pin of the Am79C930 device. A complete description of the control of the function of the TXDATA pin is described in the Multi-Function Pin section. TCR8: Start Delimiter LSB [...]
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Seite 111
P R E L I M I N A R Y AMD 111 Am79C930 Delimiter may be used for start of frame recognition by appropriate settings of the SD[1:0] bits in the Network Configuration Register (TCR0). Start of Frame detection is performed on the bits in the or- der that they appear on the medium, with the SDLT LSB, bit 0, being checked against the first bit to arrive[...]
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Seite 112
AMD P R E L I M I N A R Y 112 Am79C930 TCR13: Pin Configuration A This register is the Pin Configuration A register. This register is used to set the state of various pins as outputs or as high impedance inputs. CONFIGURATION REGISTER INDEX: 0Dh Bit Name Reset Value Description 7 LNKEN 1 Link LED Enable. LNKEN can be used to control the function of[...]
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Seite 113
P R E L I M I N A R Y AMD 113 Am79C930 value that is present on the LLOCKE pin, regardless of the setting of the PCMCIA pin. The control of the function of the LLOCKE/SA15 pin is described in the Multi-Function Pin section. 5 Reserved – Reserved. Must be written as a 0. Reads of these bits produce undefined data. 4:0 USEREN[4:0] 00h USER[4:0] Ena[...]
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Seite 114
AMD P R E L I M I N A R Y 114 Am79C930 In addition to these bits, the USER6/IRQ5 pin may be used to pro- duce interrupts to the 80188 embedded controller. This capability is controlled by the ENXSDF bit of TCR28 and the SDFU bit of TIR5 and operates independently of the bits in the table above. 2 USER5EN 0 USER5 Enable. USER5EN, the USER5FN bit of [...]
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Seite 115
P R E L I M I N A R Y AMD 115 Am79C930 TCR17: Baud Detect Lower Limit This register is the Baud Detect Lower Limit register (TCR17). CONFIGURATION REGISTER INDEX: 11h Bit Name Reset Value Description 7–6 Reserved – Reserved. Must be written as a 0. Reads of this bit produce undefined data. 5–0 BDLLT[5:0] 00h Baud Detect Lower Limit. This regi[...]
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Seite 116
AMD P R E L I M I N A R Y 116 Am79C930 edge baud counter. This information should be used to appropri- ately program the Baud Detect Upper Limit register. The resolution of the value in this register is the period of the CLKIN signal when the CLKGT20 bit of MIR9 is set to 0 or twice the period of the CLKIN signal when the CLKGT20 bit of MIR9 is set[...]
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Seite 117
P R E L I M I N A R Y AMD 117 Am79C930 CONFIGURATION REGISTER INDEX: 15h Bit Name Reset Value Description 3–0 BDRN[3:0] 0h Baud Detect Ratio. These bits are used to set the ratio of good to bad baud detections which will be used as the minimum ratio to de- termine that a valid signal is present on the medium. The value in this register is treated[...]
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Seite 118
AMD P R E L I M I N A R Y 118 Am79C930 CONFIGURATION REGISTER INDEX: 18h Bit Name Reset Value Description 7:6 Reserved – Reserved. Must be written as a 0. Reads of this bit produce undefined data. 5:0 SS[5:0] 00h RSSI Sample Start. The value in this register is used to determine when to capture a sample of the RSSI input for A/D conversion dur- i[...]
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Seite 119
P R E L I M I N A R Y AMD 119 Am79C930 3–0 A2DT[3:0] 1010b A/D sampling Time[3:0]. The value in the A2DT[3:0] field deter- mines the duration of time required to convert the A/D input. Each bit of resolution is equal to 4 times the CLKIN period when the CLKGT20 bit of MIR9 is set to 0 and is equal to 8 times the CLKIN period when the CLKGT20 bit [...]
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Seite 120
AMD P R E L I M I N A R Y 120 Am79C930 TCR26: Reserved This register is the TAI reserved location register. CONFIGURATION REGISTER INDEX: 1Ah Bit Name Reset Value Description 7–0 Reserved – Reserved. Must be written as a 0. Reads of this bit produce undefined data. TCR27: TIP LED Scramble This register is the Network Interface Polarity register[...]
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Seite 121
P R E L I M I N A R Y AMD 121 Am79C930 be high assert, such that when the TGAP2 counter expires, the TXMOD pin will be driven to a HIGH logic level. TCR28: Clear Channel Assessment Configuration This register is the Clear Channel Assessment Configuration register. The bits in this register are used to determine which features will be used to determ[...]
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Seite 122
AMD P R E L I M I N A R Y 122 Am79C930 is set to a 0, the Baud Detect Count for Stop Diversity is not used in the stop diversity decision logic. 1 UBDCS 0 Use Baud Detect of Carrier Sense in CCA decision. When this bit is set to a 1, the Baud Detect Count for Carrier Sense becomes one input to the clear channel assessment logic. When this bit is se[...]
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Seite 123
P R E L I M I N A R Y AMD 123 Am79C930 then a 16-bit deep serial FIFO is inserted into the TX data path. This FIFO allows for some mismatch to be tolerated in the clock rates between the Am79C930 internal transmit clock and the external TXC clock that is connected to the TXC input. Because of this inter- nal FIFO, the appearance of transmit data fr[...]
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Seite 124
AMD P R E L I M I N A R Y 124 Am79C930 PCMCIA CCR Registers and PCMCIA CIS Space Two bytes of attribute memory space have been used by the Am79C930 device for storage of two card configuration registers. These two registers are found at attribute memory locations 800h and 802h. The Configuration Option Register is located at Attribute memory locati[...]
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Seite 125
P R E L I M I N A R Y AMD 125 Am79C930 When written with a 1, the PWRDWN bit generates an interrupt to the 80188, requesting that the 80188 core place the Am79C930 de- vice into the power down state. The interrupt is signaled in MIR0, bit 5. If written with a 0 while in power down mode, power down mode is exited. When written with a 1, value read w[...]
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Seite 126
AMD P R E L I M I N A R Y 126 Am79C930 ABSOLUTE MAXIMUM RATINGS Storage Temperature: –65 to +150 ° C . . . . . . . . . . . . Ambient Temperature Under Bias: –65 to +125 ° C . . . Supply Voltage to AV SS or DV SS (AV DD , DV DD ): –0.3 to +6 V . . . . . . . . . . . . . . Stresses above those listed under Absolute Maximum Ratings may cause pe[...]
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Seite 127
P R E L I M I N A R Y AMD 127 Am79C930 DC CHARACTERISTICS (continued) 5.0 V Am79C930 DC Characteristics Parameter Symbol Parameter Description Test Conditions Min Max Units I DDPD2 Power Supply Current Power Down mode 40 mA CLKIN = internally cutoff, PMX1 = 32.768 kHz, no host interface accesses occurring V IN ≤ V OL or V IN ≥ V OH I DDPD3 Powe[...]
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Seite 128
AMD P R E L I M I N A R Y 128 Am79C930 ABSOLUTE MAXIMUM RATINGS Storage Temperature: –65 to +150 ° C . . . . . . . . . . . . Ambient Temperature Under Bias: –65 to +125 ° C . . . Supply Voltage to AV SS or DV SS (AV DD , DV DD ): –0.3 to +6 V . . . . . . . . . . . . . . Stresses above those listed under Absolute Maximum Ratings may cause pe[...]
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P R E L I M I N A R Y AMD 129 Am79C930 DC CHARACTERISTICS (continued) 3.3 V Am79C930 DC Characteristics Parameter Symbol Parameter Description Test Conditions Min Max Units I DDPD2 Power Supply Current Power Down mode 5 mA CLKIN = internally cutoff, PMX1 = 32.768 kHz, no host interface accesses occurring V IN ≤ V IL or V IN ≥ V OH I DDPD3 Power[...]
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AMD P R E L I M I N A R Y 130 Am79C930 ABSOLUTE MAXIMUM RATINGS Storage Temperature: –65 to +150 ° C . . . . . . . . . . . . Ambient Temperature Under Bias: –65 to +125 ° C . . . Supply Voltage to AV SS or DV SS (AV DD , DV DD ): –0.3 to +6 V . . . . . . . . . . . . . . Stresses above those listed under Absolute Maximum Ratings may cause pe[...]
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P R E L I M I N A R Y AMD 131 Am79C930 AC CHARACTERISTICS 5.0 AND 3.3 V PCMCIA INTERFACE ABSOLUTE MAXIMUM RATINGS Storage Temperature: –65 to +150*C . . . . . . . . . . . . Ambient Temperature Under Bias: –65 to +125*C . . . Supply Voltage to AV SS or DV SS (AV DD , DV DD ): –0.3 to +6 V . . . . . . . . . . . . . . Stresses above those listed[...]
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AMD P R E L I M I N A R Y 132 Am79C930 PCMCIA MEMORY WRITE ACCESS Parameter Symbol Parameter Description Test Conditions Min Max Unit t AVWL Address setup to WE ↓ 20 ns t AVWH Address setup to WE ↑ 100 ns t WMAX Write recovery time (Address hold from WE ↑ )2 0 n s t ELWH CE setup to WE ↑ 140 ns t ELWL CE setup to WE ↓ 0n s t GHEH CE hold [...]
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P R E L I M I N A R Y AMD 133 Am79C930 PCMCIA I/O READ ACCESS Parameter Symbol Parameter Description Test Conditions Min Max Unit t AVIGL Address setup to IORD ↓ 70 ns t IGHAX Address hold from IORD ↑ 20 ns t RGLIGL REG setup to IORD ↓ 5n s t IGHRGH REG hold from IORD ↑ 0n s t ELIGL CE setup to IORD ↓ 5n s t IGHEH CE hold from IORD ↑ 20[...]
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AMD P R E L I M I N A R Y 134 Am79C930 PCMCIA I/O WRITE ACCESS Parameter Symbol Parameter Description Test Conditions Min Max Unit t AVIWL Address setup to IOWR ↓ 70 ns t IWHAX Address hold from IOWR ↑ 20 ns t RGLIWL REG setup to IOWR ↓ 5n s t IWHRGH REG hold from IOWR ↑ 0n s t ELIWL CE setup to IOWR ↓ 5n s t IWHEH CE hold from IOWR ↑ 2[...]
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P R E L I M I N A R Y AMD 135 Am79C930 AC CHARACTERISTICS 5.0 AND 3.3 V ISA INTERFACE ABSOLUTE MAXIMUM RATINGS Storage Temperature: –65 to +150 ° C . . . . . . . . . . . . Ambient Temperature Under Bias: –65 to +125 ° C . . . Supply Voltage to AV SS or DV SS (AV DD , DV DD ): –0.3 to +6 V . . . . . . . . . . . . . . Stresses above those lis[...]
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AMD P R E L I M I N A R Y 136 Am79C930 ISA ACCESS Parameter Symbol Parameter Description Test Conditions Min Max Unit t i 1 LA[23:17] valid setup to BALE ↓ 60 ns t i 2 BALE ↑ to BALE ↓ pulse width 25 ns t i 3 LA[23:17] valid hold from BALE ↓ 12 ns t i 4 LA[23:17] valid setup to CMD ↓ Note 1 80 ns t i 7 SA[16:0] valid setup to CMD ↓ Note[...]
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P R E L I M I N A R Y AMD 137 Am79C930 AC CHARACTERISTICS 5.0 V MEMORY BUS INTERFACE ABSOLUTE MAXIMUM RATINGS Storage Temperature: –65 to +150 ° C . . . . . . . . . . . . Ambient Temperature Under Bias: –65 to +125 ° C . . . Supply Voltage to AV SS or DV SS (AV DD , DV DD ): –0.3 to +6 V . . . . . . . . . . . . . . Stresses above those list[...]
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AMD P R E L I M I N A R Y 138 Am79C930 MEMORY BUS WRITE ACCESS Parameter Symbol Parameter Description Test Conditions Min Max Unit t m AD MA[16:0] valid from CLKIN ↓ 26 0 n s t m CD CE active delay from CLKIN ↓ Note 1 2 60 ns t m WD MWE active delay from CLKIN ↓ 26 0 n s t m CQ MD[16:0] driven from CLKIN ↓ 2n s t m CV MD[16:0] valid from CL[...]
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P R E L I M I N A R Y AMD 139 Am79C930 AC CHARACTERISTICS 3.3 V MEMORY BUS INTERFACE ABSOLUTE MAXIMUM RATINGS Storage Temperature: –65 to +150 ° C . . . . . . . . . . . . Ambient Temperature Under Bias: –65 to +125 ° C . . . Supply Voltage to AV SS or DV SS (AV DD , DV DD ): –0.3 to +6 V . . . . . . . . . . . . . . Stresses above those list[...]
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AMD P R E L I M I N A R Y 140 Am79C930 MEMORY BUS WRITE ACCESS Parameter Symbol Parameter Description Test Conditions Min Max Unit t m AD MA[16:0] valid from CLKIN ↓ 2 100 ns t m CD CE active delay from CLKIN ↓ Note 1 2 100 ns t m WD MWE active delay from CLKIN ↓ 2 100 ns t m CQ MD[7:0] driven from CLKIN ↓ 2n s t m CV MD[7:0] valid from CLK[...]
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P R E L I M I N A R Y AMD 141 Am79C930 AC CHARACTERISTICS 5.0 V TAI INTERFACE ABSOLUTE MAXIMUM RATINGS Storage Temperature: –65 to +150 ° C . . . . . . . . . . . . Ambient Temperature Under Bias: –65 to +125 ° C . . . Supply Voltage to AV SS or DV SS (AV DD , DV DD ): –0.3 to +6 V . . . . . . . . . . . . . . Stresses above those listed unde[...]
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AMD P R E L I M I N A R Y 142 Am79C930 5.0 V TAI INTERFACE AC CHARACTERISTICS Parameter Symbol Parameter Description Test Conditions Min Max Unit T CLKIN CLKIN Period MIR9[7]=1 25 ns T CLIN CLKIN Low time MIR9[7]=1 5 ns T CHIN CLKIN High time MIR9[7]=1 5 ns T CLKIN CLKIN Period MIR9[7]=0 50 T CLIN CLKIN Low time MIR9[7]=0 22 T CHIN CLKIN High time [...]
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P R E L I M I N A R Y AMD 143 Am79C930 Notes: 1. Only applicable when TXC has been configured as an INPUT. 2. Only applicable when TXC has been configured as an OUTPUT. 3. MIN value not tested. 4. Parameter calculated from other parameters. 5. Clock period must correlate to data rate as specified in DR bits of TCR30. Note that data rate is a functi[...]
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AMD P R E L I M I N A R Y 144 Am79C930 AC CHARACTERISTICS 3.3 V TAI INTERFACE ABSOLUTE MAXIMUM RATINGS Storage Temperature: –65 to +150 ° C . . . . . . . . . . . . Ambient Temperature Under Bias: –65 to +125 ° C . . . Supply Voltage to AV SS or DV SS (AV DD , DV DD ): –0.3 to +6 V . . . . . . . . . . . . . . Stresses above those listed unde[...]
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P R E L I M I N A R Y AMD 145 Am79C930 3.3 V TAI INTERFACE AC CHARACTERISTICS Parameter Symbol Parameter Description Test Conditions Min Max Unit t CLKIN CLKIN Period 50 ns t CLIN CLKIN Low time 22 ns t CHIN CLKIN High time 22 ns t INHL CLKIN Fall time Note 8 3 ns t INLH CLKIN Rise time Note 8 3 ns t RXC RXC Period Note 5 1000 ns t CLRX RXC Low tim[...]
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AMD P R E L I M I N A R Y 146 Am79C930 AC CHARACTERISTICS 5.0 AND 3.3 V USER PROGRAMMABLE PINS ABSOLUTE MAXIMUM RATINGS Storage Temperature: –65 to +150 ° C . . . . . . . . . . . . Ambient Temperature Under Bias: –65 to +125 ° C . . . Supply Voltage to AV SS or DV SS (AV DD , DV DD ): –0.3 to +6 V . . . . . . . . . . . . . . Stresses above [...]
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P R E L I M I N A R Y AMD 147 Am79C930 AC CHARACTERISTICS 5.0 AND 3.3 V IEEE 1149.1 INTERFACE ABSOLUTE MAXIMUM RATINGS Storage Temperature: –65 to +150 ° C . . . . . . . . . . . . Ambient Temperature Under Bias: –65 to +125 ° C . . . Supply Voltage to AV SS or DV SS (AV DD , DV DD ): –0.3 to +6 V . . . . . . . . . . . . . . Stresses above t[...]
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AMD P R E L I M I N A R Y 148 Am79C930 TIMING WAVEFORMS PCMCIA Bus Interface Waveforms A n , REG CE OE D o (Dout) t A VQV t ELQV t GLQV t GLQNZ t GHAX t GHQZ WE (high) W AIT t ELGL t AVG L t GHEH t GL WTV t WTL WTH t QVWTH 20138B-10 Figure 4. PCMCIA MEMORY READ Access Timing Diagram A n , REG CE WE D i (Din) t EL WH t WL WH t WMDX W AIT t EL WL[...]
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P R E L I M I N A R Y AMD 149 Am79C930 20138B-12 A n REG IORD D o (Dout) W AIT t A VIGL CE t IGHRGH t RGLIGL t IGHAX t ELIGL t IGLIGH t IGL WTL t WTL WTH t IGHEH t WTHQV t IGHQX t IGLQV INP ACK t IGLIAL t IGHIAH t IGHQZ t IGQNZ Figure 6. PCMCIA I/O READ Access Timing Diagram A n REG IO WR D i (Din) W AIT t A VIWL CE t IWHRGH t RGLIWL tI WHAX t ELIW[...]
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AMD P R E L I M I N A R Y 150 Am79C930 ISA Bus Interface Waveforms 20138B-14 ** CMD = one of: MEMR , MEMW , IOR , IOW LA n CMD** SD out (read) t i 1 t i 8 t i 34 t i 3 t i 14 IOCHRD Y t i 7 t i 4 t i 20 AEN BALE SA n t i 2 t i 10 SD in (write) t i 11 t i 12 t i 13 t i 15 t i 21 t i 22 t i 23 t i 25 t i 26 t i 30 t i 31 t i 32 t i 9 t i 16 F[...]
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P R E L I M I N A R Y AMD 151 Am79C930 Memory Bus Interface Waveforms 20138B-15 MA n FCE, SCE, XCE MOE MD i (Din) t m AA t m OE t m AD MWE (high) CLKIN t m RDSC t m ACS t m H data sampled at this point valid t m RI t m RDHC t m AD t m CD t m OD t m OLZ t m HZ CLKOUT (internal) t m CD t m OD t m AH t m CH Figure 9. Memory Bus READ Access Timing Diag[...]
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AMD P R E L I M I N A R Y 152 Am79C930 CLOCK WAVEFORMS 20138B-17 CLKIN 0.8 V 2.0 V t CLIN t INHL t CLKIN t INLH t CHIN 0.8 V TXC 0.8 V 2.0 V t CL TX t TXHL t TXC t TXLH t CHTX 0.8 V RXC 0.8 V 2.0 V t CLRX t RXHL t RXC t RXLH t CHRX 0.8 V Figure 11. CLOCK Timing Diagram[...]
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P R E L I M I N A R Y AMD 153 Am79C930 TAI WAVEFORMS 20138B-18 **ICO = Internally Controlled Output ICO* RCO** RCO** t n 1 CLKIN CLKOUT (internal) t n 2 RCO** t n 3 t n 4 Figure 12. TAI Timing Diagram 20138B-19 RXD t RXDS RXC t RXDS TXD t TXDD TXC (input) TXD t TXDV TXC (output) t TXDS t TXDH Figure 13. Serial Data Timing Diagram[...]
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AMD P R E L I M I N A R Y 154 Am79C930 PROGRAMMABLE INTERFACE WAVEFORMS 20138B-20 **RCO = Register Controlled Output W AIT or IOCHRD Y RCO** (data change) CLKOUT (internal) RCO** (drive change) t u 1 t u 2 RCO** (drive change) t u 3 CLKIN Figure 14. Programmable Interface Timing Diagram[...]
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P R E L I M I N A R Y AMD 155 Am79C930 IEEE 1149.1 INTERFACE WAVEFORMS 20138B-21 TCK TDI, TMS TDO t 31 Output Signals t 25 t 30 t 32 t 34 t 37 t 36 Input Signals t 35 Figure 15. IEEE 1149.1 Timing Diagram[...]
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AMD P R E L I M I N A R Y 156 Am79C930 AC TEST REFERENCE WAVEFORMS 5.0 V PCMCIA AC Test Reference Waveform This waveform indicates the AC testing method em- ployed for all signals that are PCMCIA bus signals when the PCMCIA power supply pins are set to 5.0 V (i.e., VDDP pins = 5.0 V). 20138B-22 output measured parameter v alue input 2.4 0.8 2.8 0.5[...]
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P R E L I M I N A R Y AMD 157 Am79C930 5.0 V NON-PCMCIA AC TEST REFERENCE WAVEFORM This waveform indicates the AC testing method em- ployed for all signals that are not PCMCIA bus signals when the appropriate power supply pins are set to 5.0 V (i.e., VDDT, VDDU1, VDDU2, VDDM pins = 5.0 V). This includes ISA signals, TAI interface signals, Mem- ory [...]
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AMD P R E L I M I N A R Y 158 Am79C930 PHYSICAL DIMENSIONS PQT144 144-Pin Thin Quad Flat Pack (measured in millimeters) 1.00 REF. 1.60 MAX 11 ° – 13 ° 11 ° – 13 ° 0.50 BSC 144 1 1.35 1.45 21.80 22.20 19.80 20.20 21.80 22.20 19.80 20.20 0.17 0.27 16-038-PQT-2_AH PQT144 5-4-95 ae *For reference only. BSC is an A[...]
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A-1 Am79C930 Typical Am79C930 System Application APPENDIX A Host Computer 128K Flash 128K SRAM Am79C930 Radio or IR Transceiver PCMCIA or ISA PnP Interface 20183A-1 Figure 1: Typical Am79C930 System Application The typical Am79C930 application contains a Am79C930 device, a Flash memory device (up to 128 Kbytes), an SRAM [...]
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AMD A-2 Am79C930 1. Command and status communication 2. Data buffer areas 3. Am79C930 80188 core variable space After performing these functions, the device driver will enable the 80188 core by writing to a register to release the RESET of the Am79C930 80188 core. The Am79C930 80188 core will then begin fetching instruc- tions from the Flash memory[...]
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T rademarks Copyright © 1998 Adv anced Micro De vices, Inc. All rights reser ved. AMD , the AMD logo, and combinations thereof are trademarks of Adv anced Micro De vices, Inc. Am186, Am386, Am486, Am29000, b IMR, eIMR, eIMR+, GigaPHY , HIMIB, ILACC , IMR, IMR+, IMR2, ISA-HUB, MACE, Magic P acket, PCnet, PCnet- F AST , PCnet- F AST +, PCnet-Mobile,[...]