Go to accumulation fund center to seal what data should take
Publish: 2021-05-04 19:47:00
1. The sealing up of provident fund is generally handled by the personnel department of the company. With the employee's resignation certificate and account information, you can go to the housing provident fund management center to handle the sealing up proceres.
2. The required data for the preservation of the provident fund are: the original and of my ID card; Detailed list of changes in housing accumulation fund remittances
process of sealing up Provident Fund:
1. Within 30 days after the termination of the wage relationship, the unit shall go to the handling bank to seal up the employee's personal housing provident fund account, and seal up the employee's personal housing provident fund account in the unit's housing provident fund account< 2. If the laid-off workers stop paying the housing provident fund with the approval of the workers' Congress and the consent of the workers themselves, they should also go through the sealing proceres and seal them in the unit account
3. Centralized storage: the original unit transfers the balance of the employee's housing provident fund to the centralized storage account of housing provident fund within 30 days for unified storage and management< 1. The employees of the merged or bankrupt enterprise have not signed the labor contract with the new unit
2
3
4. The employee resigns, or is dismissed or dismissed by the company, or does not work again
5
6. The units approved to postpone the payment of housing provident fund are within the approved period of postponement
7. Other reasons need to be sealed.
process of sealing up Provident Fund:
1. Within 30 days after the termination of the wage relationship, the unit shall go to the handling bank to seal up the employee's personal housing provident fund account, and seal up the employee's personal housing provident fund account in the unit's housing provident fund account< 2. If the laid-off workers stop paying the housing provident fund with the approval of the workers' Congress and the consent of the workers themselves, they should also go through the sealing proceres and seal them in the unit account
3. Centralized storage: the original unit transfers the balance of the employee's housing provident fund to the centralized storage account of housing provident fund within 30 days for unified storage and management< 1. The employees of the merged or bankrupt enterprise have not signed the labor contract with the new unit
2
3
4. The employee resigns, or is dismissed or dismissed by the company, or does not work again
5
6. The units approved to postpone the payment of housing provident fund are within the approved period of postponement
7. Other reasons need to be sealed.
3. Proceres for seal up:
1. The unit shall apply for seal up to the seal up office within 30 working days after terminating the labor relationship with the employee
2. The unit shall fill in the detailed list of changes in housing provident fund account and affix the official seal
3. The information of the personnel to be sealed up shall be listed in the "reced remittance this month"
4, If the seal management office passes the review, it will print the "review form of centralized management of sealed housing provident fund households" and submit it to the unit, and the seal up is completed
note: the cases that can handle the seal up of housing provident fund accounts include:
1. When the unit changes or terminates, it is unable to handle the transfer proceres of employees' housing provident fund accounts< 2. The employee's contract has expired and will not be extended or dismissed within the term of the contract, and has not been employed in other units
3. The employee resigns, or is dismissed or removed by the company, but is not employed in other companies< 4. The employee is sentenced or reecated through labor
5. The employee and the unit agree to retain the social security relationship, except that the employee voluntarily continues to deposit through the original unit< 6. When employees enter the reemployment center, the original unit has been closed or stopped proction
7. Employees stay without pay, except those who voluntarily continue to deposit through the original unit
8. If the employee's salary income is interrupted e to other circumstances, his / her housing provident fund account will be sealed up upon his / her application.
1. The unit shall apply for seal up to the seal up office within 30 working days after terminating the labor relationship with the employee
2. The unit shall fill in the detailed list of changes in housing provident fund account and affix the official seal
3. The information of the personnel to be sealed up shall be listed in the "reced remittance this month"
4, If the seal management office passes the review, it will print the "review form of centralized management of sealed housing provident fund households" and submit it to the unit, and the seal up is completed
note: the cases that can handle the seal up of housing provident fund accounts include:
1. When the unit changes or terminates, it is unable to handle the transfer proceres of employees' housing provident fund accounts< 2. The employee's contract has expired and will not be extended or dismissed within the term of the contract, and has not been employed in other units
3. The employee resigns, or is dismissed or removed by the company, but is not employed in other companies< 4. The employee is sentenced or reecated through labor
5. The employee and the unit agree to retain the social security relationship, except that the employee voluntarily continues to deposit through the original unit< 6. When employees enter the reemployment center, the original unit has been closed or stopped proction
7. Employees stay without pay, except those who voluntarily continue to deposit through the original unit
8. If the employee's salary income is interrupted e to other circumstances, his / her housing provident fund account will be sealed up upon his / her application.
4. 1. Completed and stamped with the official seal of the unit or the special seal for housing provident fund business "housing provident fund (supplementary housing provident fund) centralized storage inventory"
2. One of the following evidential materials for the termination of labor relationship between the indivial and the original unit:
(1) of the notice of employee retirement
(2) a of the approval form for the dissolution of working relationship of personnel in organs (organizations) and institutions
(3) a of the certificate of termination of working relationship of personnel of organs (organizations) and institutions
(4) copies of legal documents (such as court judgments) of judicial organs
(5) written materials on termination of labor relations between other units and employees.
2. One of the following evidential materials for the termination of labor relationship between the indivial and the original unit:
(1) of the notice of employee retirement
(2) a of the approval form for the dissolution of working relationship of personnel in organs (organizations) and institutions
(3) a of the certificate of termination of working relationship of personnel of organs (organizations) and institutions
(4) copies of legal documents (such as court judgments) of judicial organs
(5) written materials on termination of labor relations between other units and employees.
5. After you leave, your company will not continue to pay for you, so they will go to the provident fund management center to handle internal sealing. Of course, if you have not found a new company, if you can't transfer out the provident fund relationship after one month's internal sealing, you will be classified into centralized sealing, that is to say, the provident fund management department will manage such personnel relationship, Your provident fund has been stopped since the month when the unit handled the internal sealing for you. You can continue to pay after you have a new unit. If you do not pay after two years of resignation, you can go to the provident fund management center to apply for withdrawal. If the unit has transferred you to the centralized storage, you can handle it with your valid certificate and provident fund card. If not, the fund will be in your account until you buy a house or the new unit continues to pay< How to deal with the provident fund after resignation:
1. For a non local account, provide ID card (with a ), resignation certificate and provident fund account book, and go to the provident fund center to handle it.
2. If it is a local account, it can not be withdrawn, but can be used to provide housing with provident fund loan (the interest rate is lower than the general loan interest rate), Full withdrawal is allowed after the account holder reaches the age of 45.
1. For a non local account, provide ID card (with a ), resignation certificate and provident fund account book, and go to the provident fund center to handle it.
2. If it is a local account, it can not be withdrawn, but can be used to provide housing with provident fund loan (the interest rate is lower than the general loan interest rate), Full withdrawal is allowed after the account holder reaches the age of 45.
6. CPU has a history of more than 20 years since its initial development. During this period, according to the word length of processing information, CPU can be divided into four bit microprocessors, eight bit microprocessors, sixteen bit microprocessors, thirty-two bit microprocessors, sixty-four bit microprocessors and so on. In 1971, the early Intel company launched the world's first microprocessor 4004, which is the first four bit microprocessor for computers. It contains 2300 transistors. Due to its poor performance, its market response is very unsatisfactory
subsequently, Intel company developed 8080 processor and 8085 processor, together with MC6800 microprocessor of Motorola Company and Z80 microprocessor of ZILOG company at that time, they formed a family of eight bit microprocessors
the typical proct of 16 bit microprocessor is Intel 8086 microprocessor and the mathematical coprocessor, namely 8087. These two chips use compatible instruction sets, but some instructions are added in 8087 instruction set, which are specially used for logarithm, exponent and trigonometric function. Because these instructions are applied to 8086 and 8087, they are called x86 instruction set. Since then, Intel launched a new generation of CPU procts, which are compatible with the original x86 instructions< In 1979, Intel introced 8088 chip, which is still a 16 bit microprocessor with 29000 transistors, 4.77mhz clock frequency, 20 bit address bus and 1MB Memory. The internal data bus of 8088 is 16 bits and the external data bus is 8 bits. In 1981, 8088 chip was used in IBM PC for the first time. If 8080 processor is not well known, then 8088 can be said to be a household name. The first generation CPU of personal computer PC started from it. Although the 80286 chip in 1982 is a 16 bit chip, it already contains 134000 transistors, and the clock frequency has reached an unprecedented 20MHz. Its internal and external data bus are 16 bits, address bus is 24 bits, can use 16MB memory, can use real mode and protection mode<
the representative proct of 32-bit microprocessor is Intel 80386, which was launched in 1985. It is a full 32-bit microprocessor chip and the first 32-bit chip in the x86 family. It contains 275000 transistors with a clock frequency of 12.5mhz, and then graally increased to 33MHz. The internal and external data bus of 80386 are 32 bits, and the address bus is 32 bits, which can address to 4GB memory. In addition to real mode and protection mode, it also adds a virtual 86 working mode, which can simulate multiple 8086 processors at the same time to provide multi task capability. *** Its internal data bus is 32 bits, the same as 80386, and its external data bus is 16 bits. In other words, the internal processing speed of 80386sx is close to that of 80386. It also supports real multitasking operation, and it can accept the development of I / O interface chip for 80286. The performance of 80386sx is better than that of 80286, but the price is only one third of 80386. 386 processor has no built-in coprocessor, so it can't execute floating-point operation instructions. If you need to carry out floating-point operation, you must buy an extra expensive 80387 coprocessor chip< At the end of 1980s and the beginning of 1990s, 80486 processor was put on the market. It integrated 1.2 million transistors, and the clock frequency was graally increased from 25MHz to 50MHz. 80486 integrates 80386, math coprocessor 80387 and 8KB cache in one chip. RISC (reced instruction set) technology is used in x86 series for the first time. It can execute an instruction in one clock cycle. It also adopts burst bus mode, which greatly improves the speed of data exchange with memory. Because of these improvements, the performance of 80486 is four times higher than that of 80386 with 80387 coprocessor. The early 486 can be divided into two types: the 486dx with coprocessor and the 486sx without coprocessor, and their prices are quite different. With the continuous development of chip technology, the frequency of CPU is getting faster and faster, and the external devices of PC are limited by the process, which hinders the further improvement of the main frequency of CPU. In this case, the frequency doubling technology of CPU appears, which makes the internal working frequency of CPU 2-3 times of the external frequency of processor. The names of 486dx2 and 486dx4 come from it< In the mid-1990s, a new generation of 586 processor, which surpasses 486, came out. In order to get rid of the confusion of processor names in the 486 era, Intel, the largest CPU manufacturer, named its new generation proct Pentium to distinguish amd from Cyrix. AMD and Cyrix also launched K5 and 6x86 processors to deal with Intel, respectively. However, e to the best performance of Pentium processor, Intel has graally occupied most of the market<
since then, I don't need to say that we all have a good understanding of the development of CPU. In early 1997, Pentium MMX was launched, in the middle of this year, Pentium II and AMD K6 were launched, at the end of the year, Cyrix 6x86mx was launched, and in 1998, PII, Celeron, K6-2 and MII were all in the market. Since the launch of Pentium II, Intel has given up the aging socket 7 market and pushed for the advanced slot 1 architecture. However, this time, Intel has made a mistake. With the growth of global demand for low-cost PCs less than US $1000, AMD's K6-2 processor has filled the gap of Intel in this low-end field, with AGP bus technology and 100MHz external frequency, These technologies that could only be realized on slot 1 were also realized in the era of super 7, which was first advocated by AMD. Although the performance of K6-2 and super 7 still lags behind that of PII with the same dominant frequency, amd still gained nearly 30% of CPU retail market share e to its low price. AMD is not afraid of the strong attitude, won the favor of many consumers
unfortunately, in 1999, in the face of Intel's fierce counterattack, amd began to decline, and its market sales were very poor. Cyrix was defeated in the processor war. It wanted to rely on ns to make a comeback, but it was too late. Finally, it was acquired by via, a chipset manufacturer, in June
two new processors, IDT and rise, have their own unique features in technology innovation and market positioning. IDT's winchip C6 and winchip c6-2 are mainly for low-end home market, while rise's processors are mainly for mobile computer. In mid-1999, just one month after Cyrix was acquired, Weisheng acquired IDT company. At the same time, rise was also acquired by SIS (silicon technology), another chipset manufacturer. Then it came out that rise quit the PC processor market and focused on the home appliance processing chip market, After readjustment, the PC processor market presents a new tripartite situation: Intel continues to occupy most of the market share with its excellent procts and good market operation; Amd launched athlon-k7 in August, making K7 the fastest processor in the history that surpasses Intel's similar procts in performance for the first time, and its market share has a trend of further expansion; After acquiring Cyrix and IDT, via integrates the latest technologies of the two companies and plans to launch socket 370 compatible Joshua Joshua processor in early 2000, focusing on the low-end market. In a word, with the fierce competition, all companies are trying their best to develop the latest, fastest and best processor procts for consumers.
Pentium III, the glory at the end of the century:
in early 1999, Intel released the third generation of Pentium III processor, Pentium III. the first batch of Pentium III processors used Katmai kernel, with two main frequencies of 450 MHz and 500 MHz, The most important feature of this kernel is to update the multimedia instruction set named SSE, which adds 70 new instructions to MMX to enhance 3D and floating-point applications, and is compatible with all previous MMX programs
however, to be fair, except for the SSE Instruction Set mentioned above, the Pentium III of Katmai kernel has not attracted much attention. It still basically retains the architecture of Pentium II, adopting 0.25 micron technology, 100 MHz external frequency, slot1 architecture, and 512 KB L2 cache (running at half speed of CPU), so the performance improvement is not significant. However, when Pentium III was just listed, there was a great upsurge. Some people once bought the first batch of Pentium III at a high price of more than 10000 yuan
the first generation of Pentium III processor (Katmai)
can be greatly improved from 500MHz to 1.13GHz, and the overclocking performance can be greatly improved by more than 50%. In addition, its secondary cache is also synchronized with the main frequency of CPU, but the capacity is reced to 256Kb
the second generation Pentium III processor (copermine)
in addition to the process improvements, some copermine Pentium III also has 133MHz bus frequency and socket 370. In order to distinguish them, Intel adds a "B" after the Pentium III model with 133MHz bus and an "e" after the socket 370 socket, for example, 550MHz frequency, The socket370 Pentium III with an external frequency of 133MHz is called 550eb
seeing that Pentium III, the core of Coppermine, is very popular, Intel began to switch the Celeron processor to this core. In the middle of 2000, it launched the Celeron processor with Coppermine 128 core, commonly known as celeron2. Due to the switch of 0.18 technology, the overclocking performance of Celeron has made another leap, and the overclocking range can reach 100%<
second generation Celeron (Coppermine 128 core) processor
AMD's Jedi counterattack Athlon
in the beginning, amd launched k6-3 processor to fight against Pentium III. The k6-3 processor is a three-layer cache (trilevel) architecture. It has 64K level 1 cache (Level 1) and 256K Level 2 cache (Level 2) built in, and level 3 cache (Level 3) is configured on the motherboard. The k6-3 processor also supports enhanced 3D now! Instruction set. Due to the cost and yield problems, k6-3 processor is not very successful in the desktop market, so it graally disappears from the desktop market and moves into the notebook market
what really makes amd proud is the original Athlon processor code K7. Athlon has a 3way superscalar RISC core (3way superscalar RISC core) with superscalar, superpipeline and multipipeline. It adopts 0.25 micron process and integrates 22 million transistors. Athlon includes three decoders, three integer execution units (IEU), three address generation units (AGU), three multimedia units (floating-point operation units), Athlon can execute three floating-point instructions simultaneously in the same clock cycle, and each floating-point unit is a complete pipeline. K7 contains three decoders. The decoded macroops instructions (K7 decodes x86 instructions into macroops instructions, and converts x86 instructions with different lengths into macroops instructions with the same length, which can give full play to the power of RISC core) are sent to the instruction control unit. The instruction control unit can control (save) 72 instructions at the same time. Then the instruction is sent to the integer unit or multimedia unit. The integer unit can schele 18 instructions at the same time. Each integer unit is an independent pipeline. The scheling unit can predict the branch of instructions and execute them out of order. K7 multimedia units (also known as floating point units) have stack registers that can be renamed
subsequently, Intel company developed 8080 processor and 8085 processor, together with MC6800 microprocessor of Motorola Company and Z80 microprocessor of ZILOG company at that time, they formed a family of eight bit microprocessors
the typical proct of 16 bit microprocessor is Intel 8086 microprocessor and the mathematical coprocessor, namely 8087. These two chips use compatible instruction sets, but some instructions are added in 8087 instruction set, which are specially used for logarithm, exponent and trigonometric function. Because these instructions are applied to 8086 and 8087, they are called x86 instruction set. Since then, Intel launched a new generation of CPU procts, which are compatible with the original x86 instructions< In 1979, Intel introced 8088 chip, which is still a 16 bit microprocessor with 29000 transistors, 4.77mhz clock frequency, 20 bit address bus and 1MB Memory. The internal data bus of 8088 is 16 bits and the external data bus is 8 bits. In 1981, 8088 chip was used in IBM PC for the first time. If 8080 processor is not well known, then 8088 can be said to be a household name. The first generation CPU of personal computer PC started from it. Although the 80286 chip in 1982 is a 16 bit chip, it already contains 134000 transistors, and the clock frequency has reached an unprecedented 20MHz. Its internal and external data bus are 16 bits, address bus is 24 bits, can use 16MB memory, can use real mode and protection mode<
the representative proct of 32-bit microprocessor is Intel 80386, which was launched in 1985. It is a full 32-bit microprocessor chip and the first 32-bit chip in the x86 family. It contains 275000 transistors with a clock frequency of 12.5mhz, and then graally increased to 33MHz. The internal and external data bus of 80386 are 32 bits, and the address bus is 32 bits, which can address to 4GB memory. In addition to real mode and protection mode, it also adds a virtual 86 working mode, which can simulate multiple 8086 processors at the same time to provide multi task capability. *** Its internal data bus is 32 bits, the same as 80386, and its external data bus is 16 bits. In other words, the internal processing speed of 80386sx is close to that of 80386. It also supports real multitasking operation, and it can accept the development of I / O interface chip for 80286. The performance of 80386sx is better than that of 80286, but the price is only one third of 80386. 386 processor has no built-in coprocessor, so it can't execute floating-point operation instructions. If you need to carry out floating-point operation, you must buy an extra expensive 80387 coprocessor chip< At the end of 1980s and the beginning of 1990s, 80486 processor was put on the market. It integrated 1.2 million transistors, and the clock frequency was graally increased from 25MHz to 50MHz. 80486 integrates 80386, math coprocessor 80387 and 8KB cache in one chip. RISC (reced instruction set) technology is used in x86 series for the first time. It can execute an instruction in one clock cycle. It also adopts burst bus mode, which greatly improves the speed of data exchange with memory. Because of these improvements, the performance of 80486 is four times higher than that of 80386 with 80387 coprocessor. The early 486 can be divided into two types: the 486dx with coprocessor and the 486sx without coprocessor, and their prices are quite different. With the continuous development of chip technology, the frequency of CPU is getting faster and faster, and the external devices of PC are limited by the process, which hinders the further improvement of the main frequency of CPU. In this case, the frequency doubling technology of CPU appears, which makes the internal working frequency of CPU 2-3 times of the external frequency of processor. The names of 486dx2 and 486dx4 come from it< In the mid-1990s, a new generation of 586 processor, which surpasses 486, came out. In order to get rid of the confusion of processor names in the 486 era, Intel, the largest CPU manufacturer, named its new generation proct Pentium to distinguish amd from Cyrix. AMD and Cyrix also launched K5 and 6x86 processors to deal with Intel, respectively. However, e to the best performance of Pentium processor, Intel has graally occupied most of the market<
since then, I don't need to say that we all have a good understanding of the development of CPU. In early 1997, Pentium MMX was launched, in the middle of this year, Pentium II and AMD K6 were launched, at the end of the year, Cyrix 6x86mx was launched, and in 1998, PII, Celeron, K6-2 and MII were all in the market. Since the launch of Pentium II, Intel has given up the aging socket 7 market and pushed for the advanced slot 1 architecture. However, this time, Intel has made a mistake. With the growth of global demand for low-cost PCs less than US $1000, AMD's K6-2 processor has filled the gap of Intel in this low-end field, with AGP bus technology and 100MHz external frequency, These technologies that could only be realized on slot 1 were also realized in the era of super 7, which was first advocated by AMD. Although the performance of K6-2 and super 7 still lags behind that of PII with the same dominant frequency, amd still gained nearly 30% of CPU retail market share e to its low price. AMD is not afraid of the strong attitude, won the favor of many consumers
unfortunately, in 1999, in the face of Intel's fierce counterattack, amd began to decline, and its market sales were very poor. Cyrix was defeated in the processor war. It wanted to rely on ns to make a comeback, but it was too late. Finally, it was acquired by via, a chipset manufacturer, in June
two new processors, IDT and rise, have their own unique features in technology innovation and market positioning. IDT's winchip C6 and winchip c6-2 are mainly for low-end home market, while rise's processors are mainly for mobile computer. In mid-1999, just one month after Cyrix was acquired, Weisheng acquired IDT company. At the same time, rise was also acquired by SIS (silicon technology), another chipset manufacturer. Then it came out that rise quit the PC processor market and focused on the home appliance processing chip market, After readjustment, the PC processor market presents a new tripartite situation: Intel continues to occupy most of the market share with its excellent procts and good market operation; Amd launched athlon-k7 in August, making K7 the fastest processor in the history that surpasses Intel's similar procts in performance for the first time, and its market share has a trend of further expansion; After acquiring Cyrix and IDT, via integrates the latest technologies of the two companies and plans to launch socket 370 compatible Joshua Joshua processor in early 2000, focusing on the low-end market. In a word, with the fierce competition, all companies are trying their best to develop the latest, fastest and best processor procts for consumers.
Pentium III, the glory at the end of the century:
in early 1999, Intel released the third generation of Pentium III processor, Pentium III. the first batch of Pentium III processors used Katmai kernel, with two main frequencies of 450 MHz and 500 MHz, The most important feature of this kernel is to update the multimedia instruction set named SSE, which adds 70 new instructions to MMX to enhance 3D and floating-point applications, and is compatible with all previous MMX programs
however, to be fair, except for the SSE Instruction Set mentioned above, the Pentium III of Katmai kernel has not attracted much attention. It still basically retains the architecture of Pentium II, adopting 0.25 micron technology, 100 MHz external frequency, slot1 architecture, and 512 KB L2 cache (running at half speed of CPU), so the performance improvement is not significant. However, when Pentium III was just listed, there was a great upsurge. Some people once bought the first batch of Pentium III at a high price of more than 10000 yuan
the first generation of Pentium III processor (Katmai)
can be greatly improved from 500MHz to 1.13GHz, and the overclocking performance can be greatly improved by more than 50%. In addition, its secondary cache is also synchronized with the main frequency of CPU, but the capacity is reced to 256Kb
the second generation Pentium III processor (copermine)
in addition to the process improvements, some copermine Pentium III also has 133MHz bus frequency and socket 370. In order to distinguish them, Intel adds a "B" after the Pentium III model with 133MHz bus and an "e" after the socket 370 socket, for example, 550MHz frequency, The socket370 Pentium III with an external frequency of 133MHz is called 550eb
seeing that Pentium III, the core of Coppermine, is very popular, Intel began to switch the Celeron processor to this core. In the middle of 2000, it launched the Celeron processor with Coppermine 128 core, commonly known as celeron2. Due to the switch of 0.18 technology, the overclocking performance of Celeron has made another leap, and the overclocking range can reach 100%<
second generation Celeron (Coppermine 128 core) processor
AMD's Jedi counterattack Athlon
in the beginning, amd launched k6-3 processor to fight against Pentium III. The k6-3 processor is a three-layer cache (trilevel) architecture. It has 64K level 1 cache (Level 1) and 256K Level 2 cache (Level 2) built in, and level 3 cache (Level 3) is configured on the motherboard. The k6-3 processor also supports enhanced 3D now! Instruction set. Due to the cost and yield problems, k6-3 processor is not very successful in the desktop market, so it graally disappears from the desktop market and moves into the notebook market
what really makes amd proud is the original Athlon processor code K7. Athlon has a 3way superscalar RISC core (3way superscalar RISC core) with superscalar, superpipeline and multipipeline. It adopts 0.25 micron process and integrates 22 million transistors. Athlon includes three decoders, three integer execution units (IEU), three address generation units (AGU), three multimedia units (floating-point operation units), Athlon can execute three floating-point instructions simultaneously in the same clock cycle, and each floating-point unit is a complete pipeline. K7 contains three decoders. The decoded macroops instructions (K7 decodes x86 instructions into macroops instructions, and converts x86 instructions with different lengths into macroops instructions with the same length, which can give full play to the power of RISC core) are sent to the instruction control unit. The instruction control unit can control (save) 72 instructions at the same time. Then the instruction is sent to the integer unit or multimedia unit. The integer unit can schele 18 instructions at the same time. Each integer unit is an independent pipeline. The scheling unit can predict the branch of instructions and execute them out of order. K7 multimedia units (also known as floating point units) have stack registers that can be renamed
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