Merge pull request #409 from himanshudabas/second_edition

updated the "Structure of a Block"

ch09.asciidoc

@@ -15,7 +15,7 @@ One way to think about the blockchain is like layers in a geological formation,
 
 === Structure of a Block
 
-((("blocks", "structure of")))((("blockchain (the)", "block structure")))A block is a container data structure that aggregates transactions for inclusion in the public ledger, the blockchain. The block is made of a header, containing metadata, followed by a long list of transactions that make up the bulk of its size. The block header is 80 bytes, whereas the average transaction is at least 250 bytes and the average block contains more than 500 transactions. A complete block, with all transactions, is therefore 1,000 times larger than the block header. <<block_structure1>> describes the structure of a block.
+((("blocks", "structure of")))((("blockchain (the)", "block structure")))A block is a container data structure that aggregates transactions for inclusion in the public ledger, the blockchain. The block is made of a header, containing metadata, followed by a long list of transactions that make up the bulk of its size. The block header is 80 bytes, whereas the average transaction is at least 400 bytes and the average block contains more than 1900 transactions. A complete block, with all transactions, is therefore 10,000 times larger than the block header. <<block_structure1>> describes the structure of a block.
 
 [[block_structure1]]
 [role="pagebreak-before"]
@@ -57,7 +57,7 @@ The nonce, difficulty target, and timestamp are used in the mining process and w
 
 Note that the block hash is not actually included inside the block's data structure, neither when the block is transmitted on the network, nor when it is stored on a node's persistence storage as part of the blockchain. Instead, the block's hash is computed by each node as the block is received from the network. The block hash might be stored in a separate database table as part of the block's metadata, to facilitate indexing and faster retrieval of blocks from disk.
 
-A second way to identify a block is by its position in the blockchain, called the pass:[<span role="keep-together"><em>block height</em>. The first block ever created is at block height 0 (zero) and is the</span>] pass:[<span role="keep-together">same block that was previously referenced by the following block hash</span>] +000000000019d6689c085ae165831e934ff763ae46a2a6c172b3f1b60a8ce26f+. A block can thus be identified two ways: by referencing the block hash or by referencing the block height. Each subsequent block added "on top" of that first block is one position "higher" in the blockchain, like boxes stacked one on top of the other. The block height on January 1, 2017 was approximately 446,000, meaning there were 446,000 blocks stacked on top of the first block created in January 2009.
+A second way to identify a block is by its position in the blockchain, called the pass:[<span role="keep-together"><em>block height</em>. The first block ever created is at block height 0 (zero) and is the</span>] pass:[<span role="keep-together">same block that was previously referenced by the following block hash</span>] +000000000019d6689c085ae165831e934ff763ae46a2a6c172b3f1b60a8ce26f+. A block can thus be identified in two ways: by referencing the block hash or by referencing the block height. Each subsequent block added "on top" of that first block is one position "higher" in the blockchain, like boxes stacked one on top of the other. The block height on January 1, 2017 was approximately 446,000, meaning there were 446,000 blocks stacked on top of the first block created in January 2009.
 
 Unlike the block hash, the block height is not a unique identifier. Although a single block will always have a specific and invariant block height, the reverse is not true—the block height does not always identify a single block. Two or more blocks might have the same block height, competing for the same position in the blockchain. This scenario is discussed in detail in the section <<forks>>. The block height is also not a part of the block's data structure; it is not stored within the block. Each node dynamically identifies a block's position (height) in the blockchain when it is received from the bitcoin network. The block height might also be stored as metadata in an indexed database table for faster retrieval.